JPWO2017183100A1 - Wireless communication apparatus and wireless communication method - Google Patents

Abstract

When the wireless communication device receives a wireless signal addressed to its own wireless communication device including a message related to path control via another wireless communication device, the wireless communication device outputs a message, and is input from the wireless communication control unit In the case of a route setting request instructing an adjacent wireless communication device via which the message is routed as an upstream route toward the gateway, a downlink route control message including address information of the own wireless communication device is transmitted on the upstream route satisfying the instruction of the route setting request. And a network control unit, the route can be fixed using RPL.

Description

  The present invention relates to a wireless communication device, and relates to a technique for updating route information in a network composed of a plurality of wireless communication devices.

  The application of a wireless M2M (Machine-to-Machine) system has been expanded to expand the bandwidth that is not required for licenses due to cost reduction of radio modules and frequency reorganization. The wireless M2M system is a system that transmits and receives monitoring information and control data between devices by wireless communication. In the wireless M2M system, since communication is performed with devices arranged in a wide area, extension of the communication distance is one of the problems.

  A multi-hop technology that extends the communication distance by placing a relay node between the source node and the destination node, receiving data transmitted from the source node at the relay node, and transmitting from the relay node to the destination node There is communication technology. By applying the multi-hop communication technique, it is possible to extend the communication distance between the transmission source node and the destination node without increasing the communication distance of the wireless link. One of the multi-hop communication technologies is RPL (IPv6 Routing Protocol for Low Power and Lossy Networks) standardized by IETF (see Non-Patent Document 1 below).

  In wireless communication, since the state of radio waves changes from moment to moment, regular updating of the communication path is indispensable. In RPL, nodes and gateways periodically transmit route information for route update. Each node constructs a multi-hop network with a tree structure rooted at the gateway. The node determines an upstream route in a direction from the node to the gateway based on route information periodically transmitted from the gateway. Further, the node determines a downlink route in the direction from the gateway to the other node based on route information periodically transmitted from the other node.

The update of the up route and the down route in the RPL will be described with reference to FIGS.
FIG. 19 is a diagram illustrating an example of a network configuration. The network 90 includes a gateway 91 and nodes 92a to 92c. The node 92a is adjacent to the node 92b and is an upper node of the node 92b and the node 92c. The node 92b is adjacent to the node 92c and is an upper node of the node 92c.

First, the update of the uplink route will be described.
FIG. 20 is a diagram illustrating a sequence for updating an uplink path.
The gateway sets the uplink route information in the uplink route control message, and periodically transmits the message (S801). The node 92a that has received the upstream route control message from the gateway updates the upstream route information to the gateway (S802). The node 92a sets the updated uplink route information in the uplink route control message and transmits it by broadcast (S803). The node 92b receives the uplink route control message from the node 92a, and updates the uplink route information to the gateway (S804). The node 92b sets the updated uplink route information in the uplink route control message and transmits it by broadcast (S805). The node 92c receives the uplink route control message from the node 92b, and updates the uplink route information to the gateway (S806). The node 92c sets the updated uplink route information in the uplink route control message and transmits it by broadcast (S807).

Next, update of the downlink route will be described.
FIG. 21 is a diagram illustrating a sequence for updating a downlink route. The nodes 92a to 92c periodically transmit the downlink route control message to adjacent upper nodes by unicast.
The node 92c transmits a downlink route control message by unicast to the node 92b which is an adjacent higher node (S901). The node 92b that has received the downlink control message updates the downlink information to the node 92c (S902). In addition, the node 92b transmits a downlink route control message in which the updated downlink route information is set to the adjacent upper node node 92a (S903). The node 92a that has received the downlink control message updates the downlink information to the node 92c (S904). In addition, the node 92a transmits a downlink route control message in which the updated downlink route information is set to the gateway (S905). The gateway that has received the downlink route control message updates the downlink route information to the node 92c (S906).

IETF RFC 6550, “IPv6 Routing Protocol for Low-Power and Lossy Networks”

  However, the RPL has a problem that the route is dynamically updated and the route cannot be fixed.

  The present invention has been made to solve the above-described problems, and an object of the present invention is to obtain a wireless communication apparatus that fixes a route when RPL is used.

  The wireless communication device according to the present invention includes: a wireless communication control unit that outputs a message when receiving a wireless signal addressed to its own wireless communication device including a message related to path control via another wireless communication device; and a wireless communication control unit In the case of a route setting request instructing an adjacent wireless communication device through which the input message goes to the gateway as an upward route toward the gateway, the uplink route satisfying the route setting request instruction with the downlink control message including the address information of the own wireless communication device And a network control unit that transmits the data.

  According to the present invention, a route can be fixed using RPL.

FIG. 3 is a diagram illustrating an example of a network configuration according to the first embodiment. FIG. 3 is a block diagram illustrating an example of a functional configuration of a node according to the first embodiment. FIG. 3 is a block diagram illustrating an example of a hardware configuration of a node according to the first embodiment. FIG. 3 is a diagram illustrating an example of a format of a route setting request according to the first embodiment. 5 is a flowchart showing processing of a network control unit according to the first embodiment. 5 is a flowchart showing processing of a network control unit according to the first embodiment. The schematic diagram which shows the operation | movement which the gateway which concerns on Embodiment 1 sets a fixed path | route to a node. FIG. 6 is a diagram showing an example of a fixed route list held by the route storage unit according to the first embodiment. The schematic diagram which shows the operation | movement which the node which concerns on Embodiment 1 receives DIO from a node. The schematic diagram which shows the operation | movement which the gateway which concerns on Embodiment 1 sets an exclusion path | route to a node. FIG. 6 is a diagram showing an example of an excluded route list held by a route storage unit according to the first embodiment. The schematic diagram which shows the operation | movement which the node which concerns on Embodiment 1 receives DIO from a node. FIG. 3 is a schematic diagram illustrating an operation in which a node according to the first embodiment receives DIO from the node. 5 is a flowchart showing processing of a network control unit according to the first embodiment. FIG. 4 is a block diagram illustrating an example of a functional configuration of a node according to the second embodiment. FIG. 4 is a block diagram illustrating an example of a hardware configuration of a node according to the second embodiment. 9 is a flowchart showing processing of a network control unit according to the second embodiment. 9 is a flowchart showing processing of a network control unit according to the second embodiment. The figure which shows an example of a network structure. The sequence diagram which shows the process which updates an upstream path | route. The sequence diagram which shows the process which updates a downlink path | route.

Embodiment 1 FIG.
First, the network configuration of the present invention will be described.
FIG. 1 is a diagram illustrating an example of a configuration of a network 10 according to the first embodiment. The network 10 is a network including a gateway 11 and nodes 12a to 12d as wireless communication devices. The network 10 is a network having a tree structure with the gateway 11 as a root. The gateway 11 constructs a network, and transmits / receives data to / from the node directly or via another node. The gateway 11 transmits / receives data to / from devices connected to a higher level of the gateway 11 and other networks.

  The direction from the node to the gateway 11 is up, and the direction from the gateway 11 to the node is down. The nodes 12a and 12b are subordinate nodes of the gateway 11, and a route with the gateway 11 has already been established. The node 12c exists at a distance that allows wireless communication with the node 12a and the node 12b, but a path has not yet been established. The node 12d is a lower node of the node 12c, and a route with the node 12c is established. The links 13a to 13e are links between nodes. A solid line in FIG. 1 indicates that a route has already been established. The dotted line in FIG. 1 indicates that the route has not yet been established. For example, in the case of a route between the gateway 11 and the node 12a, the gateway 11 holds down route information to the node 12a, and the node 12a holds up route information to the gateway 11. State.

Next, the configuration of the node 12a that is the wireless communication apparatus of the present invention will be described. The configuration of the nodes 12b to 12d is the same as that of the node 12a.
FIG. 2 is a block diagram illustrating an example of a functional configuration of the node 12a according to the first embodiment. The node 12a includes an application unit 21, a network control unit 22, a path storage unit 23, a wireless communication control unit 24, a network interface control unit 25, and a sensor interface control unit 26. A wireless antenna 30 is connected to the wireless communication control unit 24. The network interface control unit 25 transmits / receives data to / from another network connected to the node 12a. The data may be control information. A sensor 27 is connected to the sensor interface controller 26.

  FIG. 3 is a block diagram illustrating an example of a hardware configuration of the node 12a according to the first embodiment. The node 12a includes a memory 31, a processor 32, a sensor interface 33, a network interface 34, and a wireless interface 35. The processor 32 is connected to the memory 31 and performs temporary storage of data necessary for calculation and storage of data. The processor 32 is connected to the sensor interface 33, the network interface 34, and the wireless interface 35, and controls each interface according to instructions from the processor 32. Further, the wireless interface 35 is connected to the wireless antenna 30 and transmits and receives wireless signals.

  The memory 31 stores programs and data for realizing the functions of the application unit 21, the network control unit 22, the wireless communication control unit 24, the network interface control unit 25, and the sensor interface control unit 26. The memory 31 stores data for realizing the function of the path storage unit 23. The memory includes, for example, a ROM (Read Only Memory), a RAM (Random Access Memory), a HDD (Hard Disk Drive), and an SSD (Solid State Drive).

The processor 32 reads the program and data stored in the memory 31 and implements the functions of the application unit 21, the network control unit 22, and the wireless communication control unit 24. The processor 32 is realized by a processing circuit such as a CPU that executes a program stored in the memory 31 and a system LSI (Large Scale Integration).
A plurality of processing circuits may cooperate to execute the functions of the application unit 21, the network control unit 22, and the wireless communication control unit 24.

The sensor interface 33 realizes the function of the sensor interface control unit 26.
The network interface 34 realizes the function of the network interface control unit 25.

Next, transmission / reception of radio signals with other nodes will be described.
First, a case where a radio signal is received from another node will be described.
The radio antenna 30 receives a radio signal transmitted from another node and outputs it to the radio communication control unit 24. The wireless communication control unit 24 converts the wireless signal input from the wireless antenna 30 into a frame and confirms the destination of the frame. Two addresses, a MAC address and a network address, are set as the destination. The MAC address is a destination indicating the next node on the route. The network address is a destination of a frame delivery destination.

  The wireless communication control unit 24 outputs the frame destination to the network control unit 22 when the destination of the frame is the same as the MAC address of the own node, and discards the frame when the destination is different from the own MAC address. The network control unit 22 confirms the destination network address of the frame input from the wireless communication control unit 24. When the destination network address is different from the network address of the own node, the network control unit 22 refers to the route list of the route storage unit 23, and determines the MAC address of the next transfer node from the route information of the node having the destination network address. read out. The network control unit 22 outputs the read MAC address and frame to the wireless communication control unit 24.

  When the network address is the same as the network address of the own node and the application data is included in the data portion of the frame, the network control unit 22 sends the data portion of the frame input from the wireless communication control unit 24 to the application unit 21. Output. The application unit 21 outputs the data to the network interface control unit 25 or the sensor interface control unit 26 according to the data contents. When the data includes control information of the network connected to the network interface control unit 25, the application unit 21 outputs the control information to the network interface control unit 25. Further, when the control information of the sensor 27 is included in the data, the application unit 21 outputs the control information to the sensor interface control unit 26.

  When the network address of the frame input from the wireless communication control unit 24 is the same as the network address of the own node and the route control message is included in the data portion of the frame, the network control unit 22 The route list held by the route storage unit 23 is updated accordingly.

Next, a case where a radio signal is transmitted to another node will be described.
When data is input from the network interface control unit 25, the application unit 21 outputs data to the network control unit 22. When a measurement value is input from the sensor 27, the sensor interface control unit 26 performs a process of converting the data into a format specified in advance, and outputs the data to the application unit 21. The application unit 21 outputs the data input from the network interface control unit 25 or the sensor interface control unit 26 and the destination network address to the network control unit 22. The network control unit 22 sets the data input from the application unit 21 in the data portion of the frame, and sets the destination network address in the header of the frame. In addition, the network control unit 22 inquires of the route storage unit 23 about the MAC address of the node to be transferred next. The network control unit 22 outputs the MAC address and frame acquired from the path storage unit 23 to the wireless communication control unit 24. The wireless communication control unit 24 sets the MAC address input from the network control unit 22 in the header of the frame. The radio communication control unit 24 converts the frame into a radio signal and outputs the radio signal to the radio antenna 30.

  The network control unit 22 generates a route control message from the route information held by the route storage unit 23, and sets the route control message in the data portion of the frame. In addition, the network control unit 22 inquires of the route storage unit 23 about the MAC address of the next node to be transferred, and outputs the acquired MAC address and frame to the wireless communication control unit 24. The network control unit 22 outputs the frame to the wireless communication control unit 24, and the wireless communication control unit 24 transmits the frame to another node via the wireless antenna 30.

  In RPL, DIO ((Direct-Oriented Directed Acrylic Information) (DODAG)) is used for uplink path control. DAO (Destination Advertisement Object) is used for control of the downstream path.

Each node can grasp the route to the gateway 11 and other nodes by DIO and DAO. The route list of the route storage unit 23 of each node holds route information to the gateway 11 and other nodes. As the route information of the gateway 11 and other nodes, the address of the destination device, the address of the next node, the rank information, and the validity period are stored. The address of the next node is an address of an adjacent node on the route to the destination device. The rank information is a value calculated from values such as the number of hops to the gateway 11 and the radio wave reception intensity. The lower rank information is more suitable as a route in terms of the number of hops and radio wave conditions. The node determines a route by selecting a node having low rank information. The effective period is an effective period of the route information. The route information whose valid period has passed is discarded. The route list holds uplink route information to the gateway 11 and downlink route information to lower nodes.
The network control unit 22 holds the address, rank information, and validity period of its own node. The effective period is an effective period of the route information and is a value specified in advance as a parameter.

Next, an operation when an uplink route is instructed by a route setting request will be described.
First, the format of the route setting request will be described.
FIG. 4 is a diagram illustrating an example of a format of a route setting request according to the first embodiment. The route setting request includes a message type field, a route setting field, a route number field, and a route field. In the message type, an identifier indicating a route setting request is set. In the route setting field, fixed route valid, excluded route valid or invalid is set. The fixed route valid indicates that the route indicated by the route field is set as a fixed route. The excluded route valid indicates that the route indicated by the route field is set as an excluded route. Invalid indicates that the fixed route and the excluded route that are already set are invalidated. The number of routes set in the route field is set in the route number field. In the route field, the network address of the node is set as a setting target route. When N is set in the route number field, N routes are set in the route field.

Next, a case where the node 12c receives a route setting request will be described as an example.
FIG. 5 is a flowchart showing processing of the network control unit 22 according to the first embodiment. The network control unit 22 of the node 12c starts processing when it receives a route setting request from the gateway 11 via the node 12a. The network control unit 22 determines the route setting value of the route setting request (step S301). When the route setting is set to enable the fixed route, the network control unit 22 performs a process of enabling the fixed route of the node 12c (step S302). The network control unit 22 registers the route indicated by the route field in the fixed route list as processing for validating the fixed route, and ends the processing. The fixed route list is held by the route storage unit 23 (step S303).

  In step S301, when the route setting is set to enable the excluded route, the network control unit 22 performs a process of enabling the excluded route of the node 12c (step S304). The network control unit 22 registers the route indicated by the route field in the excluded route list as processing for validating the excluded route, and ends the processing. The route saving unit 23 holds the excluded route list (step S305). In step S301, when the route setting is set to invalid, the network control unit 22 performs processing of invalidating the fixed route list and the excluded route list held by the route storage unit 23 (step S306). The network control unit 22 initializes the fixed route list and the excluded route list held by the route storage unit 23 as a process of invalidating the fixed route list and the excluded route list (step S307), and ends the process.

Next, an operation in which the node 12c sets an uplink route will be described.
FIG. 6 is a flowchart showing processing of the network control unit 22 according to the first embodiment. The network control unit 22 of the node 12c starts processing when receiving DIO from the node 12a. The network control unit 22 determines the current route setting (step S401). When the fixed route and the excluded route are set to be invalid, the network control unit 22 selects the uplink route based on the route information notified by the received DIO. The network control unit 22 determines an uplink path according to the RPL standard protocol. For example, there are a method of selecting by the shortest number of relays and a method of selecting by the strength of received electric field strength. The network control unit 22 sets the adjacent upper node determined as the uplink route as the next node address of the uplink route information (step S402). Subsequently, the network control unit 22 transmits a DAO that is a downlink route control message to the upper node determined as the uplink route. When the node 12a is selected as the upstream route, the network control unit 22 transmits DAO to the node 12a. As described above, the upper node sets the downlink route information to the node 12c by receiving DAO (step S403).

  On the other hand, if the fixed path is set to be valid in step S401, the network control unit 22 determines whether the source network address (node 12a) of the received DIO is registered in the fixed path list (step S404). When the transmission source network address (node 12a) of the DIO is registered in the fixed route list, the network control unit 22 sets the node 12a as the next node address of the upstream route information to the gateway 11 (step S402). DAO is transmitted to 12a (step S403). When the transmission source network address (node 12a) of the DIO is not registered in the fixed route list, the network control unit 22 discards the received DIO because it is not a DIO notified from the fixed route. Here, the network control unit 22 does not set an uplink route and does not transmit DAO (step S405).

  If the exclusion route is set to be valid in step S401, the network control unit 22 determines whether or not the transmission source network address (node 12a) of the received DIO is registered in the exclusion route list (step S406). When the source network address (node 12a) of the received DIO is registered in the excluded route list, the network control unit 22 discards the received DIO because of the DIO notified from the excluded route. The network control unit 22 does not set an uplink route and does not transmit DAO (step S405). When the source network address (node 12a) of the received DIO is not registered in the excluded route list, the network control unit 22 sets the node 12a as the next node address of the uplink route information to the gateway 11 (step S402). The DAO is transmitted to the node 12a (step S403).

Next, an operation for setting a fixed route will be described using a specific example.
FIG. 7 is a schematic diagram illustrating an operation in which the gateway 11 according to the first embodiment sets a fixed route to the node 12c.
When the gateway 11 sends a route setting request for setting the link 13c to a fixed route to the node 12c, the fixed route is valid in the route setting field, the route number field is 1, and the network address of the node 12a is in the route field. Is set.

FIG. 8 is a diagram illustrating an example of a fixed route list held by the route storage unit 23 according to the first embodiment. When the link 13c is set as a fixed route, the network address of the node 12a is set in the fixed route list of the node 12c as shown in FIG.
FIG. 9 is a schematic diagram illustrating an operation in which the node 12c according to the first embodiment receives DIO from the nodes 12a and 12b. When the node 12a is registered in the fixed route list of the node 12c, when the node 12c receives DIO from the node 12a registered in the fixed route list, the node 12a selects the node 12a as an upstream route, and sets DAO to the node 12a. Send. Further, when the node 12c receives DIO from the node 12b not registered in the fixed path list, the node 12c discards the received DIO. Therefore, the node 12c sets an uplink route that passes through the node 12a set as a fixed route.

Next, an operation for setting an exclusion route will be described using a specific example.
FIG. 10 is a schematic diagram illustrating an operation in which the gateway 11 according to the first embodiment sets an exclusion route in the node 12c.
When the gateway 11 sends a route setting request for setting the link 13d as an excluded route to the node 12c, the excluded route is valid in the route setting field, the route number field is 1, and the network address of the node 12b is in the route field. Is set.

FIG. 11 is a diagram illustrating an example of an excluded route list held by the route storage unit 23 according to the first embodiment. When the link 13d is set as an excluded route, the network address of the node 12b is set in the excluded route list of the node 12c as shown in FIG.
FIG. 12 is a schematic diagram illustrating an operation in which the node 12c according to the first embodiment receives DIO from the nodes 12a and 12b. When the node 12b is registered in the excluded route list of the node 12c, when the node 12c receives DIO from the node 12a that is not registered in the excluded route list, the node 12c selects the node 12a as an upstream route and transmits DAO to the node 12a. To do. Further, when the node 12c receives DIO from the node 12b registered in the excluded route list, the node 12c discards the received DIO. Therefore, the node 12c sets an uplink route that passes through a node other than the node 12b set as the excluded route.

Next, an operation for changing the fixed route will be described.
FIG. 13 is a schematic diagram illustrating an operation in which the node 12c according to the first embodiment changes the fixed path.
FIG. 14 is a flowchart showing processing of the network control unit 22 according to the first embodiment. The node 12c sets the node 12a instructed as the fixed route as the next node address of the uplink route information to the gateway 11. At this time, the network control unit 22 of the node 12c starts processing upon receiving a route setting request for setting the node 12b as a fixed route. The network control unit 22 of the node 12c refers to the fixed route list and determines whether there is a node registered in the fixed route list (step S501). When there is a node registered in the fixed route list, the network control unit 22 of the node 12c deletes the registered node 12a from the fixed route list (step S502). The network control unit 22 of the node 12c registers the node 12b notified by the route setting request in the fixed route list (step S503).

  The network control unit 22 of the node 12c determines whether or not the registered node 12a has been set as an uplink route (step S504). When the node 12a is set as the next node address of the upstream route information to the gateway 11, the network control unit 22 of the node 12c transmits DAO in which Lifetime = 0 is set to the node 12a. The node 12a that has received the DAO for which Lifetime = 0 is set, deletes the downlink information of the node 12c when the downlink information of the node 12c is held (step S505). The network control unit 22 of the node 12c transmits DAO to the node 12b notified by the route setting request (step S506). In addition, the network control unit 22 of the node 12c sets the node 12b notified by the route setting request as the next node address of the uplink route information to the gateway 11 (step S507), and ends the process.

  In step S501, if there is no node registered in the fixed route list, the process proceeds to step S506. In step S504, if the node 12a is not set as an uplink route, the process proceeds to step S506.

  In the present embodiment, it is described that the route list holds the uplink route information to the gateway 11, but the route passes through other upper nodes other than the node set as the next node address of the uplink route information to the gateway 11. Information may also be held. Further, it is possible to hold the uplink route information to the upper node.

  As described above, in the present embodiment, when a message addressed to the own node related to path control is received from another node, the wireless communication control unit 24 that outputs a message, and the message input from the wireless communication control unit are directed to the gateway. In the case of a route setting request instructing a first adjacent node that passes through as an uplink route, a network control unit 22 that transmits a downlink route control message including address information of the own node on an uplink route that satisfies the instruction of the route setting request; Therefore, the path can be fixed using RPL.

Further, the network control unit 22 is instructed by the route setting request to the uplink route via the first adjacent node, and when the uplink route control message received from the first adjacent node is input, the network control unit 22 Since the downlink route control message destined for the node is output, the route with the first adjacent node designated as the fixed route can be established.
Further, the network control unit 22 is instructed to the uplink route via the first adjacent node by the route setting request, and when the uplink route control message received from the second adjacent node is input, the network control unit 22 Since no downlink route control message destined for this node is output, it is possible not to establish a route with a second adjacent node other than the fixed route.

  In addition, when the network control unit 22 is instructed an uplink route via the first adjacent node by the route setting request and then is instructed an uplink route by the second adjacent node by a new route setting request The wireless communication control unit 24 outputs the downlink route control message input from the network control unit to the downlink control message indicating that the downlink to the own node is invalidated with the first adjacent node as the destination. Since the data is transmitted to one adjacent node, the fixed route can be changed.

Further, the network control unit 22 is instructed by the route setting request for an uplink route that excludes the third adjacent node, and when the uplink route control message received from the fourth adjacent node is input, the network control unit 22 Since the downlink route control message destined for the node is output, it is possible to establish a route with the fourth adjacent node other than the excluded route.
Further, the network control unit 22 is instructed by the route setting request for an uplink route that excludes the third adjacent node, and when the uplink route control message received from the third adjacent node is input, the network control unit 22 Since no downlink route control message destined for this node is output, it is possible to prevent establishment of a route with the third adjacent node designated as the excluded route.

  In addition, the network control unit 22 indicates that the route that excludes the third adjacent node is invalidated by a new route setting request after the uplink route that excludes the third adjacent node is instructed by the route setting request. When instructed, since the uplink route information including the address information of the third adjacent node is deleted from the excluded route list, the excluded route can be changed.

Embodiment 2. FIG.
In the first embodiment described above, the route is fixed by the route setting request. However, in the present embodiment, an embodiment in the case where a communication failure occurs in the fixed route is shown.
In the present embodiment, parts different from the first embodiment will be described.

FIG. 15 is a block diagram illustrating an example of a functional configuration of the node 12a according to the second embodiment. The difference from the functional configuration of the node 12a of the first embodiment is that a path maintenance timer 28 is added.
FIG. 16 is a block diagram illustrating an example of a hardware configuration of the node 12a according to the second embodiment. The difference from the hardware configuration of the node 12a of the first embodiment is that a timer 36 is added. The timer 36 implements the function of the path maintenance timer 28.

First, a communication failure detection method will be described.
FIG. 17 is a flowchart showing processing of the network control unit 22 according to the second embodiment. When the network control unit 22 of the node 12c receives a route setting request message with the node 12a as a fixed route, the network control unit 22 starts processing. The network control unit 22 of the node 12c starts the route maintenance timer 28 (step S601). The network control unit 22 of the node 12c waits to receive DIO from the node 12a set as the fixed path (step S602). The network control unit 22 of the node 12c determines whether DIO has been received from the node 12a set as the fixed path (step S603). When DIO is received from the node 12a, the path maintenance timer 28 is reset (step S604). If no DIO is received from the node 12a, the process proceeds to step S603.

Next, an operation for resetting a route when the route maintenance timer 28 times out will be described.
FIG. 18 is a flowchart showing processing of the network control unit 22 according to the second embodiment. When the route maintenance timer 28 times out, the network control unit 22 of the node 12c starts processing. When the route maintenance timer 28 times out, the network control unit 22 of the node 12c determines that a communication failure has occurred in the fixed route (node 12a) (step S701). When it is determined that there is a communication failure, the network control unit 22 of the node 12c collects route information of routes other than the fixed route. The collected route information is information necessary for route selection, such as the number of route relays and the received electric field strength (step S702). The network control unit 22 of the node 12c creates a communication failure notification. The communication failure notification includes the occurrence of the communication failure and the collected route information (step S703).

  The network control unit 22 of the node 12c sets a temporary route in order to notify the communication failure notification to the gateway 11. At this time, the network control unit 22 selects an adjacent upper node that passes as an uplink route from the collected route information. Here, it is assumed that the node 12b is selected as the upper node (step S704). The network control unit 22 of the node 12c transmits a communication failure notification to the gateway 11 via the node 12b, and ends the process (step S705).

  The gateway 11 transmits a route setting request to the node 12c based on the communication failure notification received from the node 12c. By receiving the route setting request from the gateway 11, the node 12c resets the route. The route setting request transmitted by the gateway 11 may be, for example, one that sets the node 12a as an excluded route or one that sets the node 12b as a fixed route.

  In the present embodiment, it is described that the network control unit 22 sets a temporary uplink route from the collected route information. However, the route information that passes through a node other than the route that is determined to have a communication failure is routed. If the list holds, the stored uplink route information may be used as a temporary route.

  As described above, in the present embodiment, the network control unit 22 receives the route setting request indicating the uplink route that passes through the first adjacent node, even if a predetermined time has elapsed. When the uplink route control message is not received from one adjacent node, a communication failure notification for notifying the communication failure of the first adjacent node is transmitted to the gateway via the other adjacent node, so that the communication failure occurs on the fixed route. And the gateway 11 can grasp that a communication failure has occurred in the fixed path. When the gateway 11 knows that a communication failure has occurred in the fixed path, it can set a new fixed path.

DESCRIPTION OF SYMBOLS 10, 90 Network 11, 91 Gateway 12a-e, 92a-c Node 13a-e Link 21 Application part 22 Network control part 23 Path | route preservation | save part 24 Wireless communication control part 25 Network interface control part 26 Sensor interface control part 27 Sensor 28 Path | route Maintenance timer 30 Wireless antenna 31 Memory 32 Processor 33 Sensor interface 34 Network interface 35 Wireless interface 36 Timer

Claims (12)

A wireless communication control unit that outputs the message when receiving a wireless signal addressed to its own wireless communication device including a message related to path control via another wireless communication device;
In the case of a route setting request for instructing an adjacent wireless communication device through which the message input from the wireless communication control unit passes as an upward route toward the gateway, a downlink route control message including address information of the own wireless communication device is sent to the route A network control unit that transmits on an upstream route that satisfies a setting request instruction;
A wireless communication apparatus comprising: The network control unit receives an uplink route control message received from the first adjacent wireless communication device when an uplink route via the first adjacent wireless communication device is instructed by the route setting request And outputting the downlink route control message addressed to the first adjacent wireless communication device,
The wireless communication device according to claim 1, wherein the wireless communication control unit transmits the downlink control message input from the network control unit to the first adjacent wireless communication device.   The network control unit is instructed by the route setting request to an uplink route that passes through the first adjacent wireless communication device, and an uplink route control message received from the second adjacent wireless communication device is input, The radio communication apparatus according to claim 2, wherein the downlink path control message destined for the second adjacent radio communication apparatus is not output. Provided with a route storage unit that holds route information related to the upstream route,
When the network control unit is instructed by the route setting request for an uplink route that passes through the first adjacent wireless communication device, the network control unit obtains uplink route information including address information of the first adjacent wireless communication device. The wireless communication apparatus according to claim 2, wherein the wireless communication apparatus is registered in a fixed route list of a route storage unit.   The network control unit is instructed to use an uplink route that passes through the first adjacent wireless communication device according to the route setting request, and then passes through the first adjacent wireless communication device according to a new route setting request. The wireless communication according to claim 4, wherein when instructed to invalidate a route, uplink route information including address information of the first adjacent wireless communication device is deleted from the fixed route list. apparatus. The network control unit is directed to an uplink route that passes through the first adjacent wireless communication device by the route setting request and then passes through a second adjacent wireless communication device by a new route setting request. Is output a downlink route control message to invalidate the downlink route to the own wireless communication device with the first adjacent wireless communication device as a destination,
6. The radio communication control unit according to claim 2, wherein the radio communication control unit transmits the downlink path control message input from the network control unit to the first adjacent radio communication device. Wireless communication device.   The network control unit is configured to receive the first adjacent wireless communication even if a predetermined time elapses after receiving the route setting request indicating the uplink route via the first adjacent wireless communication device. When an uplink route control message is not received from a device, a communication failure notification for notifying a communication failure of the first adjacent wireless communication device is transmitted to the gateway via another adjacent wireless communication device. The wireless communication apparatus according to any one of claims 2 to 6. The network control unit is instructed by the route setting request an uplink route that excludes the third adjacent wireless communication device, and when an uplink route control message received from a fourth adjacent wireless communication device is input, Outputting the downlink control message destined for the fourth adjacent wireless communication device;
8. The radio communication control unit according to claim 1, wherein the radio communication control unit transmits the downlink route control message input from the network control unit to the fourth adjacent radio communication device. 9. Wireless communication device.   The network control unit is instructed by the route setting request to an uplink route that excludes the third adjacent wireless communication device, and an uplink route control message received from the third adjacent wireless communication device is input 9. The wireless communication apparatus according to claim 8, wherein the downlink path control message destined for the third adjacent wireless communication apparatus is not output. Provided with a route storage unit that holds route information related to the upstream route,
When the network control unit is instructed by the route setting request to an uplink route that excludes the third adjacent wireless communication device, the network control unit obtains uplink route information including address information of the third adjacent wireless communication device. The wireless communication apparatus according to claim 8 or 9, wherein the wireless communication apparatus is registered in an excluded route list of a route storage unit.   The network control unit is configured to specify a route for excluding the third adjacent wireless communication device by a new route setting request after an uplink route to exclude the third adjacent wireless communication device is instructed by the route setting request. The radio communication apparatus according to claim 10, wherein when instructed to be invalidated, uplink path information including address information of the third adjacent radio communication apparatus is deleted from the excluded path list. A radio communication control step of outputting the message when receiving a radio signal addressed to the own radio communication device including a message related to path control via another radio communication device;
In the case of a route setting request instructing an adjacent wireless communication device via which the message input from the wireless communication control step passes as an upward route toward the gateway, a downlink route control message including address information of the own wireless communication device is sent to the route. A network control step for transmitting via an upstream route that satisfies the setting request instruction;
A wireless communication method.

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