DE112015006595B4 - Radio communication device and radio communication method - Google Patents

Abstract

A radio communication device configured for operation in a multi-hop network having a tree structure, and for repetitive wake and rest conditions, the radio communication device comprising:
a network controller (24) for holding information about paths for sending data to other radio communication devices and generating a path control message containing the information about paths; and
a radio transmitting / receiving unit (22) for transmitting the path control message generated by the network control unit to an adjacent radio communication device when a data request is received from an adjacent radio communication device, the data request indicating that the adjacent radio communication device has been started from the idle state and the Sending data requests.

Description

Technical area

The present invention relates to a technique of transmitting travel information to a radio communication device that configures a multi-hop network and performs intermittent control.

State of the art

The application of a machine-to-machine (M2M) radio system is expanding to reduce the cost of a radio module and to extend a bandwidth that does not require a license to reorganize frequencies. The M2M radio system is a system that transmits / receives monitoring information and control data between devices by radio communication. Since the M2M radio system communicates with the widely arranged devices, the extension of a communication distance is considered to be one of the problems. Furthermore, since it is assumed that a radio node is installed in an environment in which a power supply can not be ensured, it is also one of the problems to reduce the power consumption so that the radio node can be battery-powered for a long time.

As a technique of extending the communication distance, there is a multi-hop communication technology in which a relay node is installed between a transmission source node and a destination node, data sent from the transmission source node is received from the relay node, and the data is sent from the relay node to the destination node. By applying the multi-hop communication technology, it is possible to increase a communication distance between the transmission source node and the destination node without extending a communication distance of a radio link. As one of the multi-hop communication technologies, IPv6 Routing Protocol for Low Power and Lossy Networks (RPL) is standardized by IETF (see Non-Patent Document 1 below).

RPL periodically exchanges control messages to update a communication path. In radio communication, since a state of a radio wave changes from moment to moment, it is essential to periodically update the path. Each node establishes a multi-hop network with a tree structure with a gateway as a branch. There is a path (hereinafter referred to as an upward path) in a direction from the own node to the gateway and a path (hereinafter referred to as a down path) in a direction from the gateway to the own node. Each of the paths is updated by the following means.

First, the updating of the upstream path will be described.

The gateway sets uplink path information in an uplink control message and periodically broadcasts the uplink control message. A node that has received the uplink control message updates uplink path information held by itself, sets the updated uplink path information in the uplink control message, and broadcasts the uplink control message.

9 Figure 13 is a diagram illustrating a sequence of updating the uplink path. In 9 the nodes A to C are present. The node A is adjacent to the node B and is a low level node of the node B and the node C. The node B is a low level node adjacent to the node C.

The node C having received the up-link control message updates up-path information held by it, sets the updated up-path information in the up-path control message, and broadcasts the up-path control message (FIG. S901 ). Node B receives the uplink control message from node C and updates the uplink path information (FIG. S902 ). Node B places its own updated uplink path information in the uplink control message and broadcasts the uplink control message (FIG. S903 ). Node A receives the uplink control message from node B and updates the uplink path information (FIG. S904 ).

Next, the update of the downlink will be described.

10 Fig. 10 is a diagram illustrating a process of updating the downlink path. In 10 there are nodes A through C. Nodes A through C send a downlink control message to a neighboring higher level node.

The node A directionally sends the down-path control message to the node B ( S1001 ). Node B, which is the downlink path Has received control message updates downlink path information ( S1002 ). Further, node B sends the updated downlink control message to node C (FIG. S1003 ). The node C that has received the downlink control message updates downlink path information (FIG. S1004 ).

On the other hand, as a technique of realizing low power consumption, there is an intermittent control in which a node repeats awake and sleep states. For example, in IEEE802.15.4e, Receiver Initiated Transmission (RIT) is standardized as a method of intermittent control (see below Non-Patent Document) 2 ).

11 Fig. 10 is a diagram illustrating a flow of intermittent control by RIT. In 11 nodes A and B are present. Nodes A and B are adjacent to each other and nodes forming a multi-hop network. Nodes A and B repeat awake and sleep states. The node B knows in advance that the node A is an intermittent control performing node.

Even if node B receives data addressed to node A from another node, node B does not immediately forward the data ( S1101 ). Upon entering the awake state, the node A sends a data request requesting the transmission of the data to the neighboring node B (FIG. S1102 ). Node B receives the data request from node A, thereby sending the data addressed to node A ( S1103 ). Node A receives the data and rests at idle times according to an intermittent cycle.

CITATION

patent literature

US 2007/0211681 A1 : Sun et al. "Method and System for Frequency Agility in a Wireless Sensor Network" discloses a radio communication device comprising a network controller, as well as a radio transmitter / receiver unit adapted for operation in a multi-hop network with a tree structure and for repetitive wake and rest conditions is configured. The radio communication device is configured to send a message generated by the network controller to an adjacent radio communication device when a data request is received from the adjacent radio communication device indicating that the adjacent radio communication device has been started from idle and is requesting the transmission of data Message contains synchronization information for the adjacent radio communication device.

US 2013/0265909 A1 : Park et al. "METHOD OF EXTENDING ROUTING PROTOCOL FOR M2M SERVICES IN WIRELESS MESH NETWORK" discloses a method of transmitting path control messages in a wireless mesh network of radio communication devices.

Non-patent literature

• Non-Patent Document 1: IETF RFC6550, "IPv6 Routing Protocol for Low-Power and Lossy Networks"
• Non-Patent Document 2: IEEE Std 802.15.4e-2012

Summary of the invention

Technical problem

However, in a case where a method of updating a communication path by RPL of the non-patent document 1 with intermittent control by RIT of the non-patent document 2 is combined, a problem arises that a broadcast path control message can not be received at a time Node is sleeping, and path information can not be updated.

The present invention aims to solve the above-described problem. The primary purpose of the present invention is to obtain a radio communication apparatus capable of updating a communication path even when a node constituting a multi-hop network performs intermittent control.

the solution of the problem

A radio communication device configured for operation in a multi-hop network with a tree structure, and for repeated wake and hibernation, the radio communication device comprising: a network control unit for holding information on paths for sending data to other radio communication devices and Generating a path control message containing the information about paths; and a radio transmitting / receiving unit for transmitting the path control message generated by the network control unit to an adjacent radio communication device when a data request is received from an adjacent radio communication device, the data request indicating that the adjacent radio communication device has started from the idle state into the awake state; and requesting the sending of data.

Advantageous Effects of the Invention

According to the present invention, it is possible to update a communication path even if a node constituting a multi-hop network performs intermittent control.

list of figures

• 1 FIG. 10 is a block diagram illustrating a configuration of a network according to a first embodiment. FIG.
• 2 FIG. 10 is a block diagram illustrating a configuration of a node according to a first embodiment. FIG.
• 3 FIG. 12 is a flowchart illustrating a flow of a receiving operation of the node according to the first embodiment. FIG.
• 4 FIG. 12 is a flowchart illustrating a procedure of a transmission operation of the node according to the first embodiment. FIG.
• 5 FIG. 15 is a diagram illustrating a procedure of updating an up-link of the node according to the first embodiment. FIG.
• 6 Fig. 15 is a diagram illustrating a procedure of updating a down-link of the node according to the first embodiment.
• 7 FIG. 15 is a block diagram illustrating an example of a hardware configuration of the node according to the first embodiment. FIG.
• 8th FIG. 10 is a flowchart illustrating a process of updating a path by a network control unit according to a second embodiment. FIG.
• 9 Fig. 10 is a diagram illustrating a flow of updating an uplink path.
• 10 Fig. 10 is a diagram illustrating a flow of updating a downlink path.
• 11 Fig. 10 is a diagram illustrating a flow of intermittent control by RIP.

Description of exemplary embodiments

First embodiment

First, a network configuration according to the present invention will be described.

1 FIG. 15 is a diagram illustrating a configuration of a network according to a first embodiment. FIG. The network is a multi-hop network that uses nodes 10a to c and a gateway 11 is configured as a radio communication device. Furthermore, the network is after 1 a network with a tree structure with the gateway 11 as a branch. The gateway 11 forms and manages the network and sends / receives data directly to / from the node or via another node. Furthermore, the gateway sends / receives 11 Data to / from a device having an upper level from the gateway 11 or another network.

A direction from the node to the gateway 11 is up, and one direction from the gateway 11 to the node is down. In 1 is a path that connects to the node 10a , the knot 10b and the node 10c is connected from the gateway 11 built over another node. The knot 10a is a node of lower level of the node 10b and the knot 10c , The knot 10b is a node of lower level of the node 10c , and a node of higher level of the node 10a , The node c is a node of higher level of the node a and the node b. It should be noted that the nodes 10a to c perform an intermittent control.

Next is a configuration of a node 10 described. The knots 10a to c have the same configuration as the node 10 ,

2 is a block diagram showing the configuration of the node 10 illustrated according to the first embodiment.

The knot 10 is with an antenna 21 a radio transmitting / receiving unit 22, an application data transmitting / receiving unit 23 , a network control unit 24 and an intermittent control unit 25 configured. Furthermore, the network control unit 24 with an upstream path management unit 26 and a down-path management unit 27 configured. Furthermore, the intermittent control unit 25 with a node management unit 28 and a wake state management unit 29 configured. There is a case in which a sensor is connected to the node 10 is connected, and the application data transmitting / receiving unit 23 sends / receives data to / from the sensor.

First, a case will be described in which the node 10 Receives data.

The antenna 21 receives a radio signal from another node, thereby sending the radio signal to the radio transmitter / receiver unit 22 outputs. The radio transmitter / receiver unit 22 converts the radio signal into a frame and checks destinations of the frame. In the frame, two types of network address and a MAC address are set as the destinations. The network address is a destination for data of the frame to be transmitted. The MAC address is on Destination indicating a next node on a path of the multiple jump. It is sufficient as long as the network address and the MAC address are values that can uniquely identify the node. Further, regarding a transmission source, a transmission source network address and a transmission source MAC address as well as the destinations in the frame are set.

The radio transmitter / receiver unit 22 gives the data to the application data transmitting / receiving unit 23 or the network controller 24 according to details of the data of the frame to be transmitted. The application data transmitting / receiving unit 23 processed by the radio transmitter / receiver unit 22 entered application data. A path control message is received from the radio transceiver unit 22 entered, thereby updating the network controller 24 Path information.

The upward path management unit 26 holds a MAC address and rank information of a higher level node, a MAC address of a next node, and an expiration date of path information in mutual association. The rank information is a value that is a distance from the gateway 11 to the node. The distance is represented by the number of jumps, for example. The number of hops is the number of nodes that are passed up to a destination node. The MAC address of the next node is a next node on a path at a time to which data addressed at the higher level nodes is sent, and is a node adjacent to the node 10 , The upward path management unit 26 stores a transmission source MAC address of an uplink control message as the MAC address of the next node. The MAC address and the rank information of the higher level node and the expiration data of the path information are values notified by the uplink control message.

Furthermore, the down-path management unit stops 27 a MAC address and rank information of a lower level node, a MAC address of a next node, and the expiration date of path information in mutual association. The next node is a next node on a path at a time when data addressed at the lower level nodes is sent, and is a node adjacent to the node 10 , The down-path management unit 27 stores a send source MAC address of a downlink control message as the MAC address of the next node. The lower level node's MAC address and rank information and the expiration date of the path information are values communicated by the downlink control message.

There is a case in which the upstream path management unit 26 and the down path management unit 27 Contain path information from multiple nodes.

The node management unit 28 holds a MAC address of an adjacent node and information about whether each node performs intermittent control in mutual association or not. When a node enters a network, the node sends its own MAC address to surrounding nodes and information about whether or not it is performing intermittent control. Based on the information at this time, the node management unit 28 Information about whether or not the neighboring node performs intermittent control is obtained.

Furthermore, the wake state management unit stops 29 an intermittent cycle of their own knot.

Next, a case in which the node 10 Sends data described.

The application data transmitting / receiving unit 23 gives application data by the one with the node 10 connected sensor, and an application to the radio transmitter / receiver unit 22 out. The network control unit 24 refers to the upstream path management unit 26 or the down-path management unit 27 and adds information of its own node to generate the path control message. The uplink control message is formed by the MAC address and the rank information of the higher level node and the expiration date of the path. The network control unit 24 sets a MAC address of the own node to the MAC address of the upper-level node as path information of the own node. The network control unit 24 keeps Rank information of the own node and the expiration date of the path and sets held values in the up-path control message. The network control unit 24 gives the generated up-path control message and the MAC address of the next node to the radio transmission / reception unit 22 out.

The downlink control message is formed by the lower level node's MAC address and rank information and the expiration date of the path. The network control unit 24 sets the MAC address of the own node as the MAC address of the lower level node as the path information of the own node. The network control unit 24 holds the rank information of the own node and the expiration date of the path and sets held values in the down-path control message. The network control unit 24 gives the generated downlink control message and the MAC address of the next node to the radio transmission / reception unit 22 out.

The radio transmitter / receiver unit 22 asks the node management unit 28 Whether or not a next node performs intermittent control. When the next node performs intermittent control, the radio transmission / reception unit receives 22 a data request from the next node, whereby the path control message and the application data via the antenna 21 be sent to the next node. When the next node does not perform intermittent control, the radio transmission / reception unit transmits 22 the path control message and the application data to the next node without waiting to receive the data request.

Next is an operation where the node 10 Receive data from another node, described in detail.

3 Fig. 10 is a flowchart showing a procedure of a receiving operation of the node 10 illustrated according to the first embodiment.

Radio - / - receiving unit 22 receives the radio signal from the antenna 21 , making the process of one step S301 off starts.

In the step S301 determines the radio transmitter / receiver unit 22 whether or not the data of the frame to be sent is addressed at its own node. If a network destination address of the frame is the own node, the process goes to a step S302 further.

In the step S302 determines the radio transmitter / receiver unit 22 whether or not the data of the frame to be sent is the application data. If the data of the frame to be transmitted is the application data, the radio transmission / reception unit gives 22 the application data to the application data transmitting / receiving unit 23 out.

In one step S303 processes the application data transmitting / receiving unit 23 the entered application data. There is a case where the application data transmitting / receiving unit 23 continue to output the data to a sensor connected to its own node. The process ends.

In the step S302 if the data of the frame to be sent is not the application data, the process goes to a step S304 further.

In the step S304 when the data of the frame to be transmitted is the path control message, the radio transmission / reception unit 22 the path control data to the network controller 24 out.

In one step S305 updates the network controller 24 the path information. If the path control message is related to an uplink path, the network controller stores 24 the path information in the uplink f management unit 26 , When the path control message is related to a downlink path, the network controller stores 24 the path information in the down path management unit 27 , The process ends.

In the step S304 if the data of the frame to be transmitted is not the path control message, the radio transmission / reception unit 22 processing according to the details of the message, and the process ends.

In the step S301 If the network destination address of the frame is not the own node, the process goes to a step S306 further. This is a case where the frame is sent to another node.

In the step S306 When a destination MAC address of the frame is the own node, the process goes to a step S307 further.

In the step S307 The radio transmission / reception unit 22 transmits the data received from another node to the next node. Details of a process are described below.

In the step S306 If the destination MAC address of the frame is not the own node, the process goes to a step S311 further.

In the step S311 discards the radio transmitter / receiver unit 22 the frame. The process ends.

Next is an operation in which the node 10 sends the data to another node, described in detail.

4 Fig. 10 is a flowchart showing a procedure of a sending process of the node 10 illustrated according to the first embodiment. The process of this flowchart becomes in a case where the node 10 sends the generated data, and in a case where the node 10 the of transmits data received from another node. The case in which the node 10 which transmits data received from another node is the step S307 in 3 ,

The application data transmitting / receiving unit 23 sends the application data to another node in response to a process according to an input from the sensor and the received application data. The application data transmitting / receiving unit 23 gives the application data and the destination network address to the radio transmission / reception unit 22 out.

The radio transmitter / receiver unit 22 starts the process of one step S401 from at a time when the data to be transmitted from the application data transmitting / receiving unit 23 be entered.

In the step S401 gives the radio transmitter / receiver unit 22 the destination network address to the network controller 24 and asks the network controller 24 over the next node. The network control unit 24 outputs the MAC address of the next node corresponding to the destination network address to the radio transmission / reception unit. The radio transmitter / receiver unit 22 sets the from the application data transmitting / receiving unit 23 input destination network address as the destination network address of the frame. The radio transmitter / receiver unit continues to set 22 the MAC address of the next node, that of the network controller 24 was entered as the destination MAC address of the frame.

In one step S402 gives the radio transmitter / receiver unit 22 the MAC address of the next node to the intermittent control unit 25 and asks the intermittent control unit 25 Whether the next node performs intermittent control or not. The intermittent control unit 25 refers to the node management unit 28 and gives information about whether or not the next node performs intermittent control to the radio transmission / reception unit 22 out. When the next node performs intermittent control, the process goes to a step S403 further. Further, if the next node does not perform intermittent control, the process goes to a step S404 further.

In the step S403 goes when the radio transmitter / receiver unit 22 the data request from the next node is received or a timer holding transmission data expires, the process goes to a step S404 further.

In the step S404 gives the radio transmitter / receiver unit 22 a send source MAC address of the data request to the network controller 24 out. When a node that is a transmission source of the data request is a node on the upstream path, the network controller generates 24 the up-path control message and gives the generated up-path control message to the radio transmission / reception unit 22 out. The radio transmitter / receiver unit 22 sets the up-path control message in a data area of the frame and converts the frame into a radio signal. The radio transmitter / receiver unit 22 sends the radio signal via the antenna 21 to the next node.

When a node that is a transmission source of the data request is a node on the downlink path, the network controller generates 24 the down-path control message and outputs the generated down-path control message to the radio transmission / reception unit 22 out. The radio transmitter / receiver unit 22 sends the downlink control message to the next node in the same way as the uplink control message. The process goes one step S405 further.

In the step S405 sets the radio transmitter / receiver unit 22 the MAC address of the next node as the destination MAC address of the frame and sets the application data in the data area of the frame. Furthermore, the radio transceiver unit is converting 22 the frame in the radio signal and gives the radio signal to the antenna 21 out. The antenna 21 sends the radio signal to the next node. The process ends.

If the radio transmitter / receiver unit 22 does not hold the application data to be transmitted to a neighboring node at a time when the data request is received from the neighboring node, transmits the radio transmission / reception unit 22 only the path control message. At this time, the radio transceiver unit can 22 to the frame sending the path control message add information indicating that the application data to be sent is not held and sending the frame to the neighboring node.

Next, an uplink updating operation will be described. To simplify the description, the operation will be described mainly using device names.

5 FIG. 13 is a diagram illustrating a process of updating the up-path of the node 10b illustrated according to the first embodiment.

The knot 10b receives at the node 10a addressed data ( S501 ). The node management unit 28 of the node 10b determines if the node 10a a node that performs intermittent control is or is not. Because the node 10a performs an intermittent control sets the node 10b sending to the node 10a out ( S502 ). The knot 10a exits the idle state and sends the data request when entering the wake state. The knot 10b receives the data request from the node 10a , causing the uplink management unit 26 it is queried whether the node 10a is a node on the upstream path or not ( S503 ). If the node 10a the node is on the upstream path, the node sends 10b the uplink control message directed to the node 10a ( S504 ). The knot 10a updates the uplink path information based on that from the node 10b received uplink control message ( S505 ). The knot 10b receives a transmission confirmation of the up-path control message, thereby performing the transmission of the data that has been suspended ( S506 ). The knot 10a receives the data and goes to sleep at a time when the intermittent cycle occurs.

If no suspended data sent to the node 10a are addressed, at a time, to which the node 10b the data request from the node 10a receives, may be, the node 10b explicitly determine that there are no suspended data in the uplink control message and the uplink control message to the node 10a send. Explicitly determining that there is no suspended data in the uplink control message, the node may 10a be moved to a sleep state without waiting for data. Therefore, there is an effect of reducing the power consumption.

Furthermore, the node can 10b the at the node 10a Broadcast addressed uplink control message. Broadcasting allows the surrounding nodes to also receive information about the uplink path and update information.

Next, an operation of updating the downward path will be described. To simplify the description, the operation will be described mainly using device names.

6 Fig. 10 is a diagram illustrating a procedure of updating the downlink path of the node 10b illustrated according to the first embodiment.

The knot 10b receives at the node 10c addressed data ( S601 ). The node management unit 28 of the node 10b determines if the node 10c a node that performs intermittent control is or is not. Because the node 10c performs intermittent control, sets the node 10b the shipment to the node 10c out ( S602 ). The knot 10c exits the idle state and sends the data request after entering the wake state. The knot 10b receives the data request from the node 10c , whereby the down-path management unit 27 it is queried whether the node 10c is a node on the downward path or not ( S603 ). If the node 10c the node is on the downlink path, the node sends 10b the downlink control message directed to the node 10c ( S604 ). The knot 10c updates the downlink path information based on the from the node 10b received downlink control message ( S605 ). The knot 10b receives the send acknowledgment of the downlink control message, thereby sending the data that has been suspended ( S606 ). The knot 10c receives the data and is set to sleep at a time when an intermittent cycle occurs.

Next is a hardware configuration of the node 10 described.

7 is a block diagram illustrating an example of the hardware configuration of the node 10 illustrated according to the first embodiment.

The knot 10 is with a memory 71 , a processor 72 and a radio communication device 73 configured. The antenna 21 is with the radio communication device 73 connected.

The memory 71 stores a program and data representing each function of the radio transmitter / receiver unit 22 , the application data transmitting / receiving unit 23 , the network control unit 24 and the intermittent control unit 25 realize. Furthermore, the memory stores 71 Data representing each function of the upstream path management unit 26 , the down path management unit 27 , the node management unit 28 and the wake state management unit 29 realize. The memory is configured, for example, by a read-only memory (ROM), a random-access memory (RAM), a disk drive (HDD) or a solid-state memory (SSD).

The processor 72 reads the program and the data stored in the memory 71 are stored and realized every function of the radio transmitter / receiver unit 22 , the application data transmitting / receiving unit 23 , the network control unit 24 and the intermittent control unit 25 , The processor 72 is realized by a processing circuit such as a CPU or an integrated large-scale system (LSI) which executes the program stored in the memory.

It is to be noted that a plurality of processing circuits are common to perform the functions of the radio transmission / reception unit 22 , the application data transmitting / receiving unit 23 , the network control unit 24 and the intermittent control unit 25 can be configured.

The radio communication device 73 Realizes the function of the radio transmitter / receiver unit 22 along with the store 71 and the processor 72 , The radio communication device 73 is configured by a radio transmitting device and a radio receiving device, and transmits / receives a radio signal to / from another device via a radio link.

Therefore, in the present embodiment, a radio communication apparatus configuring a multi-hop network having a tree structure and a repetitive wake-and-rest state includes: a network control unit for holding information on paths for transmitting data to other radio communication devices and generating a path control message including Information about paths; and a radio transmitting / receiving unit for, when a data request is received from an adjacent radio communication device from the other radio communication devices, the data request indicating that the adjacent radio communication device has been started from retirement and requesting the transmission of data, sending the data from the network Control unit generated path control message to the adjacent radio communication device, so that it is possible to update a communication path even if the radio communication device that configures the multi-hop network, performs an intermittent control.

Second embodiment

In the above-described first embodiment, the up-path control message or the down-path control message is sent upon receiving the data request. The present embodiment describes that the path control message is sent in consideration of an expiration date of the communication path.

It should be noted that in the present embodiment, the differences from the first embodiment will be described.

8th FIG. 11 is a flowchart illustrating a process of updating the path information by the network control unit. FIG 24 illustrated according to the second embodiment.

The network control unit 24 acquires an expiration date of the uplink and an expiration date of the downlink path from the path control message, and stores the expiration date of the uplink path and the expiration date of the downlink path in the uplink management unit 26 or the downlink management unit 27 ,

The knot 10 starts the process of one step S801 out.

In the step S801 starts the network control unit 24 an up-link timer and a down-path timer. A timer value is incremented from 0.

In one step S802 receives the radio transmitter / receiver unit 22 the data request. The radio transmitter / receiver unit 22 gives the send source MAC address of the frame of the data request to the network controller 24 out. If a data request transmission source is a node on the upstream path, the process goes to a step S804 further.

In the step S803 compares the network controller 24 a value of the uplink timer with a threshold. If the value of the up-path timer is less than the threshold, the process goes to a step S805 further. If the value of the up-path is not smaller than the threshold, the process returns to the step S802 back.

In the step S804 creates the network control unit 24 the up-path control message, and gives the up-path control message to the radio transmission / reception unit 22 out. The radio transmitter / receiver unit 22 sends the uplink control message directionally over the antenna 21 ,

In one step S805 sets the network control unit 24 returns the value of the up-path timer and sets the value of the up-path timer to 0. The process returns to the step S802 back.

In the step S802 When the data source transmission source is a node on the downward path, the process goes to a step S806 further.

In the step S806 For example, a value of the downlink timer is compared to the threshold. If the value of the down-path timer is less than the threshold, the process goes to one step S807 further. If the value of the down-path timer is not less than the threshold, the process goes to the step S802 back.

In the step S807 creates the network control unit 24 the down-path control message and gives the down-path control message to the radio transmission / reception unit 22 out. The radio transmitter / receiver unit 22 sends the downlink control message directionally over the antenna 21 ,

In one step S808 sets the network control unit 24 returns the value of the down-path timer and sets the value of the down-path timer to 0. The process returns to the step S802 back.

The value compared with the up-path timer and the down-path timer is set to a value that is n times a cycle for intermittent control of the own node. The cycle of the intermittent control is a time from the awake state and rest state of the node to the awakening state of the node. n is an integer equal to 1 or more.

By setting the threshold value to a value that is n times the cycle of the intermittent control, it is possible to send the up-path and the down-path control message n times until the expiration date of the path expires. In a case where n is set equal to 1, if the transmission of the path control message has failed once, the expiration date of the path expires and updating of the path has failed. On the other hand, in a case where n is set to a large number, a transmission interval for the path control message becomes short, and a transmission time of the radio network increases, so that the power consumption of the node increases. Therefore, by adequately setting n, it is possible to reduce the failure of path updating and further suppress the increase of the occupancy of the radio network and the increase of the power consumption of the node.

Therefore, in the present embodiment, the network control unit counts a time elapsed from the output of the path control message to the radio transmission / reception unit and when the elapsed time is smaller than the threshold at a time when the data request from an adjacent radio communication device is received, the radio transmitter / receiver unit does not send the path control message so that the path can be updated before the expiration date of the path expires.

LIST OF REFERENCE NUMBERS

10, 10a to c:

node

11:

gateway

21:

antenna

22:

Radio - / - receiving unit

23:

Application Data transmission - / - receiver unit

24:

NCU

25:

intermittent control unit

26:

Upward path management unit

27:

Downward path management unit

28:

Node management unit

29:

Waking state management unit

71:

Storage

72:

processor

73:

Radio communication equipment

Claims (5)

A radio communication device configured for operation in a multi-hop network having a tree structure, and for repetitive wake and rest conditions, the radio communication device comprising: a network controller (24) for holding information about paths for sending data to other radio communication devices and generating a path control message containing the information about paths; and a radio transmission / reception unit (22) for transmitting the path control message generated by the network control unit to an adjacent radio communication device when a data request is received from an adjacent radio communication device, the data request indicating that the adjacent radio communication device has been started from the idle state and the Sending data requests. Radio communication device according to Claim 1 wherein if the radio transmitting / receiving unit does not hold data to be transmitted to the adjacent radio communication device at a time when the data request is received from the neighboring radio communication device, the radio transmitting / receiving unit adds the path control message to which information is added , the information indicating that there is no data to send. Radio communication device according to Claim 1 or 2 wherein the network controller counts a time elapsed from sending the path control message to the neighboring radio communication device, and wherein if the elapsed time is less than a threshold at a time when the data request is received from the neighboring radio communication device Radio Transmit / Receive Unit does not send the Path Control message. Radio communication device according to Claim 3 comprising an intermittent control unit (25) for holding a cycle for intermittently controlling the own device and performing intermittent control of the own device, the network control unit setting the threshold to a value that is n times (n is a positive integer) of the cycle for intermittent control of the own device. A radio communication method configured for operation in a multi-hop network having a tree structure, and for repetitive wake and rest conditions, the radio communication method comprising: a network control step of holding information about paths for sending data to other radio communication devices and generating a path control message containing the information about paths; and a radio transmission / reception step of transmitting the path control message generated in the network control step to an adjacent radio communication device when a data request is received from an adjacent radio communication device, the data request indicating that the adjacent radio communication device has been started from the idle state and transmitting data requests.

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