JP2019121156A - Sensor network system and center device - Google Patents

Abstract

To appropriately transmit information to sensor nodes.SOLUTION: A center device 116 comprises a center holding unit for holding conduit mapping capable of specifying positions where a sensor node 112 and a relay 114 are installed and holding an identifier of the relay where a sensor node has passed in association with the sensor node, and an information transmission unit for, when information for an arbitrary sensor node is generated, transmitting the information via a relay associated with the arbitrary sensor node. In the case where the information is not received by the arbitrary sensor node, the information transmission unit determines the other relay which is different from the relay associated with the arbitrary sensor node and also which is close to the arbitrary sensor node on the basis of the conduit mapping, so as to transmit information via the other relay.SELECTED DRAWING: Figure 6

Description

  The present invention relates to a sensor network system including a plurality of meters and a center device.

  Gas companies and electric power companies arrange gas meters and electricity meters at demand points in order to integrate the consumption of gas and electricity consumed by consumers. Also, in recent years, smart meters that have a communication function, perform two-way data communication with gas and electric power companies, and can automatically remotely measure the amount of gas and power used are in the spotlight There is. Such smart meters can also be used as an information source for enhancing the safety and utilization efficiency of infrastructure networks such as gas and power.

  In addition, various means have been proposed to realize data communication between the smart meter described above and a gas company or a power company. For example, a smart meter may be provided with a short distance radio to form a mesh network, a 3G or LTE (Long Term Evolution) mobile telephone network to form a star network, or power line communication to form a star network. It is conceivable to form a network.

  In addition, as an application of the mesh type network, there is known a technology that operates a smart meter stably by switching the ad-hoc communication by switching the ad-hoc communication when the main network and the ad hoc communication by wireless LAN are installed side by side. For example, Patent Document 1). In addition, a technology related to network routing is also disclosed (for example, Patent Document 2).

JP, 2012-065422, A JP 2012-105258 A

  As described above, by constructing a sensor network system connecting sensor nodes through ad hoc communication, it becomes possible to collect meter reading information (automatic meter reading) even if a meter reading person does not directly read a meter, Efficiency can be achieved.

  In such a sensor network system, a sensor node transmits information to a center device via another sensor node or relay. Then, the center device stores which of the plurality of relays the sensor node has passed through, and causes the stored relay to pass through when distributing information to the sensor node. .

  Here, when the communication environment changes, the sensor node may destabilize the communication with the relay which has been passed so far, and may transmit information to the center apparatus via a different relay. However, it may take time for the sensor device to reflect to the center apparatus that it has passed through a new repeater. Then, the center device tries to distribute information to the sensor node via the relay stored before the communication environment changes until the newly relayed relay is reflected in the center device. . In this case, information may not be properly transmitted to the sensor node.

  An object of the present invention is to provide a sensor network system and a center apparatus capable of appropriately transmitting information to a sensor node in view of such problems.

  In order to solve the above problems, a sensor node associated with each of a plurality of meters, a center device that collects meter information through the sensor node, and a relay that relays the sensor node and the center device are provided. In the sensor network system of the invention, the center device holds the conduit mapping that can identify the location where the sensor node and the repeater are installed, and retains the identifier of the repeater passed by the sensor node in association with the sensor node. The information transmission unit includes: a center holding unit; and an information transmission unit that transmits information via a relay associated with an arbitrary sensor node when the information to the arbitrary sensor node is generated. Associated with any sensor node based on conduit mapping, if any sensor node fails to receive Unlike vignetting repeater, and to determine other repeaters closer to any sensor node, and transmits the information by way of the other repeaters.

  In order to solve the above problems, a sensor node according to the present invention for collecting meter information through a sensor node associated with each of a plurality of meters and a relay connected to the sensor node includes a sensor node and a relay When the center holding unit that holds the conduit mapping that can identify the installed position and holds the identifier of the relay passed by the sensor node in association with that sensor node, and information for any sensor node is generated And an information transmitting unit that transmits information via a relay associated with any sensor node, and the information transmitting unit is based on the conduit mapping when the information can not be received by any sensor node. , Determine the other repeaters different from the repeaters associated with any sensor node and close to any sensor node, It is via the repeater transmitting information.

  According to the present invention, it is possible to appropriately transmit information to a sensor node.

It is an explanatory view showing a schematic structure of a sensor network system. It is a functional block diagram showing a schematic configuration of a meter. It is a functional block diagram showing a schematic structure of a center device. It is an explanatory view for explaining a construction procedure of a sensor network system. It is explanatory drawing for demonstrating the positional relationship of a meter and a repeater. It is explanatory drawing for demonstrating the positional relationship of a sensor node and a repeater. It is a flowchart for demonstrating the flow of information transmission processing. It is explanatory drawing for demonstrating the positional relationship of a sensor node and a repeater. It is a flowchart for demonstrating the flow of normal operation judgment processing. It is explanatory drawing for demonstrating the positional relationship of a sensor node and a repeater.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The dimensions, materials, and other specific numerical values and the like shown in this embodiment are merely examples for facilitating the understanding of the invention, and do not limit the present invention unless otherwise specified. In the specification and the drawings, elements having substantially the same functions and configurations will be denoted by the same reference numerals to omit repeated description, and elements not directly related to the present invention will not be illustrated. Do.

(Sensor network system 100)
FIG. 1 is an explanatory view showing a schematic configuration of a sensor network system 100. As shown in FIG. As shown in FIG. 1, the sensor network system 100 is configured to include a plurality of meters 110, a plurality of sensor nodes 112, a plurality of relays 114, and a center device 116.

  The meter (smart meter) 110 is installed, for example, on a customer-by-user basis, and at least uses gas or power when the gas company supplies gas to the customer or power company supplies power to the customer It is a device that automatically detects the amount. In the present embodiment, for convenience of explanation, the gas meter 110 by the gas supplier is exemplified, but it is needless to say that the present invention can be applied to electric power (electricity). The meter 110 can be identified by the identifier (meter number) of the meter 110 attached to the main body.

  FIG. 2 is a functional block diagram showing a schematic configuration of the meter 110. As shown in FIG. The meter 110 includes a shutoff valve 150, a pressure sensor 152, a flow rate sensor 154, a display unit 156, and a computing unit 158. In FIG. 2, the flow of the control signal is indicated by a solid arrow and the flow of the flammable gas is indicated by a broken arrow.

  The shutoff valve 150 includes a valve that controls the opening degree of the valve and controls the flow rate of the flammable gas flowing through the gas flow path 148. Therefore, the shutoff valve 150 can shut off the flow of combustible gas by completely closing the valve. The pressure sensor 152 is provided downstream of the shutoff valve 150 and detects the pressure of the flammable gas.

  The flow rate sensor 154 includes ultrasonic transducers 154 a and 154 b and a propagation velocity deriving unit 154 c. The ultrasonic transducers 154a and 154b are disposed downstream of the shutoff valve 150 and upstream of the pressure sensor 152 at predetermined positions on the upstream side surface and the downstream side surface of the gas flow path 148, for example, with sound waves of 20 kHz or more. It functions as a transmitter and receiver of a certain ultrasonic wave. The propagation speed deriving unit 154c detects the propagation time of the ultrasonic wave propagating between the ultrasonic transducers 154a and 154b via the flammable gas, and derives the flow rate of the flammable gas based on the propagation time.

  The display unit 156 is configured of a liquid crystal display, an organic EL (Electro Luminescence) display, etc., and is used to report an integrated value of the supply amount (use amount) of the flammable gas or an abnormality such as leakage of the flammable gas. .

  The operation unit 158 manages and controls the entire meter 110 by a semiconductor integrated circuit including a central processing unit (CPU), a PROM storing programs and the like, a RAM as a work area, and the like. The arithmetic unit 158 also functions as the shutoff control unit 160 in cooperation with the program. The shutoff control unit 160 shuts off or displays the shutoff valve 150 when the pressure of the combustible gas detected by the pressure sensor 152 or the flow rate of the combustible gas derived by the flow rate sensor 154 satisfies a predetermined shutoff condition. It warns that through the part 156 and the alarm speaker.

  Returning to FIG. 1, the sensor node 112 is installed in one-to-one correspondence with each of the meters 110 and transmits and receives information (data) used at least in the meter 110. In addition, since the identifier (sensor node number) of the sensor node 112 set inside the sensor node 112 is attached to the information, the center apparatus 116 can specify the sensor node 112 that has transmitted and received the information. it can.

  The relay (gateway device) 114 is installed in association with any of the plurality of sensor nodes 112, establishes wired communication with the associated sensor node 112, and wirelessly communicates with the center apparatus 116 through the base station 118. Establish communication. The relay 114 then establishes wireless communication with the surrounding sensor node (s) 112 through the associated sensor node 112. Therefore, the sensor node 112 always passes through one repeater 114 in order to establish communication with the center device 116.

  However, since the communication of the sensor node 112 is realized by short distance wireless communication, not all the sensor nodes 112 can directly establish wireless communication with the sensor node 112 associated with the repeater 114. In this case, the sensor node 112 is connected to the repeater 114 by hopping another sensor node 112 capable of wireless communication one or more times. Thus, the repeater 114 transfers the information of each sensor node 112 to the center device 116 through the associated sensor node 112 and other sensor nodes 112 in the surrounding, and the information of the center device 116 in the surrounding sensor nodes 112. Can be sent to At this time, since the information to be transmitted also includes the identifier (relay device number) of the repeater 114 for identifying the repeater 114 via which the information is transmitted, the center apparatus 116 can obtain the information. It is possible to identify the relay 114 that has passed through.

  The center apparatus 116 is an apparatus belonging to the manager side of the sensor network system 100 such as a gas company or a power company, which is configured by a computer or the like, collects information of one or more relays 114, or Information is transmitted to a plurality of repeaters 114.

  Here, the center device 116 manages the position (coordinate information) where the meter 110 is installed through conduit mapping (GIS system). In conduit mapping, an identifier of the meter 110 is associated with meter position information indicating a position where the meter 110 is installed. As described above, the repeater 114 is associated with the meter 110 and the sensor node 112. Therefore, the meter position information associated with the identifier of the meter 110 associated with the repeater 114 can be regarded as repeater position information indicating the position at which the repeater 114 is installed. Therefore, in the conduit mapping, the identifier of the relay 114 and the relay position information are indirectly associated via the identifier of the meter 110 and the meter position information. And the center apparatus 116 can manage the repeater position information in which the repeater 114 is installed with the meter position information in which the meter 110 is installed. In the following, for convenience of explanation, it is assumed that the identifier of the repeater 114 and the repeater position information are associated in the conduit mapping. Also, instead of the identifier of the meter 110, the sensor node 112 associated with the meter 110 may be associated with the meter position information. Thus, the center device 116 can directly or indirectly specify the positions of the meter 110, the sensor node 112, and the repeater 114 through conduit mapping. In addition, although a "position" here shows the position on a horizontal surface, you may include the position of the perpendicular direction.

  FIG. 3 is a functional block diagram showing a schematic configuration of the center device 116. As shown in FIG. The center apparatus 116 includes a center communication unit 170, a center holding unit 172, and a center control unit 174.

  The center communication unit 170 establishes wireless communication with the repeater 114 through the base station 118. The center holding unit 172 includes a ROM, a RAM, a flash memory, an HDD, and the like, and holds various information such as a program used for the center device 116 and the above-described conduit mapping. The center control unit 174 includes a CPU and a DSP (Digital Signal Processor), and controls the entire center apparatus 116 using a program stored in the center holding unit 172. Further, the center control unit 174 functions as a data acquisition unit 180, a repeater position derivation unit 182, a distance derivation unit 184, a distance determination unit 186, and an information transmission unit 188 in cooperation with the program. The data acquisition unit 180, the repeater position derivation unit 182, the distance derivation unit 184, the distance determination unit 186, and the information transmission unit 188 will be described in detail later.

  Here, communication between devices will be described. For example, between the repeater 114 and the center apparatus 116, a communication charge according to the amount of communication such as LTE (Long Term Evolution) such as a mobile phone network including the base station 118 or a PHS (Personal Handyphone System) network. Wireless communication is established through the existing pay communication network where Also, wireless communication is established between the sensor nodes 112 through the smart meter wireless system (U-Bus Air) using, for example, the 920 MHz band. The wireless communication between the sensor nodes 112 is assumed to be free of charge, but the communication cost may be lower than at least wireless communication between the repeater 114 and the center apparatus 116 regardless of whether it is paid or free. By such wireless communication, the repeater 114 is connected to the center apparatus 116 through the pay communication network, and to each sensor node 112 through the smart meter wireless system.

  In the present embodiment, the meter 110 and the sensor node 112 are arranged in units of a plurality of consumers. In addition, the repeater 114 may be put side by side. The center device 116 collects the information of the meter 110 or controls the meter 110 through the sensor node 112 and the repeater 114. Therefore, the sensor node 112 and the repeater 114 will be disposed at every position where the consumer exists.

  Here, the smart meter wireless system by the sensor node 112 and the pay communication network by the repeater 114 are used in combination at the installation site of the repeater 114. Communication between the center apparatus 116 and the sensor node 112 can be established easily and inexpensively by using the existing pay communication network without separately providing a base station dedicated to the smart meter wireless system.

  Also, in the combination of the repeater 114 and a plurality of sensor nodes 112 around it, only the repeater 114 utilizes a pay communication network, and all the other sensor nodes 112 utilize a smart meter wireless system in which no communication fee is generated. doing. Therefore, the communication cost can be significantly reduced.

  For example, through the sensor node 112 associated with itself, the repeater 114 collects information from the plurality of surrounding sensor nodes 112 through the wireless system for smart meters, and the collected information is transferred through the pay communication network on a daily basis. Transmit to the center device 116. In this way, it is possible to minimize the use of the pay communication network of the repeater 114 and to reduce the communication cost.

  Since the smart meter wireless system assumes near field wireless communication, the power consumed for wireless communication is relatively small. Therefore, the power supply of the sensor node 112 can be supplied by a battery or the like, and the power consumption of the sensor network system 100 can be reduced. A pay communication network consumes power relatively easily as compared to a smart meter wireless system, so a large capacity battery or a separate power supply is required, but the absolute number of relays 114 is smaller than that of the sensor node 112. The power consumption can be extremely low compared to the case of using the mobile phone network from all the meters 110.

(Construction of sensor network system 100)
As described above, by constructing the sensor network system 100 for connecting the sensor nodes 112, it is possible to collect meter reading information (automatic meter reading) even if the gas supplier's meter reading person does not directly read the meter 110. This can be done, and work can be made more efficient.

  However, since the sensor node 112 is associated with the meter 110, the position thereof is limited to the vicinity of the meter 110 (near the consumer home), and the communication environment between the sensor nodes 112 is also limited depending on the arrangement condition of the meter 110. It will Further, since the timing at which the meter 110 is replaced is also limited to its expiration date (the expiration date of the verification validity period), the sensor network system 100 takes into consideration the time when each sensor node 112 becomes effectively available. You have to design. Therefore, the sensor network system 100 is constructed as follows.

  FIG. 4 is an explanatory diagram for explaining a construction procedure of the sensor network system 100. The meter 110 is determined to have a test validity period of, for example, 10 years, and must be replaced upon expiration of the test validity period. However, instead of replacing all the meters 110 at once, for example, the goal is to complete the replacement of all the products after at least ten years by replacing 1/10 of the total every one year. Here, the meter 110 (or the sensor node 112 associated therewith) for which the test validity period has expired is shown in white, and the meter 110 for which the test validity period has not yet expired is shown in black.

  First, as shown in FIG. 4 (a), the meter 110 whose test valid period expires every year is extracted, and among them, a sensor node is selected as one of the meters 110 located at the customer's home "A". Not only 112 but also the repeater 114 is associated. Then, on the basis of the meter 110 associated with the repeater 114, the meter 110 associated with the repeater 114 and the consumer's house "B" located within a predetermined distance (for example, 30 m which is an average radio wave propagation distance) A predetermined number (for example, 4) of meter 110 located at customer's home "C" located within a predetermined distance from meter 110 determined to be located within a predetermined distance and a predetermined number (for example 4) Group as "."

  Subsequently, as shown in FIG. 4B, the repeater 114 is associated with the meter 110 located at another consumer end “E” of the meter 110 whose verification validity period has expired. And based on the meter 110 which matched the repeater 114, the meter 110 located in the consumer's house "F" located within the predetermined distance with the meter 110 which matched the repeater 114, and within the predetermined distance A predetermined number of meters 110 (not extracted here) located within a predetermined distance from the meter 110 determined to be located at are extracted and grouped as a group "G". Needless to say, the predetermined distance and the predetermined number are not limited to the above-mentioned values.

  As described above, by repeating the grouping as shown in FIGS. 4A and 4B, the efficient sensor network system 100 can be constructed while suppressing the absolute number of the relays 114. it can. Here, it is specified whether the meter 110 whose test validity period has expired should be replaced with a new meter 110 and sensor node 112, or whether the relay 114 should be associated. The worker may replace the meter 110 based on the information.

(Replacement of meter 110)
Since the sensor node 112 is associated with the new meter 110 along with the replacement of the meter 110, the center device 116 can manage the meter reading information of the meter 110 by the identifier of the sensor node 112.

  FIG. 5 is an explanatory view for explaining the positional relationship between the meter 110 and the repeater 114. As shown in FIG. Here, as illustrated in FIG. 5A, it is assumed that the worker associates the meter 110 and the sensor node 112 with the customer home “A” in association with the replacement of the meter 110. When the worker replaces the meter 110 of the customer home “A”, the worker associates the identifier of the installed meter 110 with the meter position information indicating the position where the meter 110 should be installed, and transmits it to the center apparatus 116 as report information. Do. Therefore, the report information includes the meter position information and the identifier of the meter 110. The position information of the meter 110 may be specified by a unique meter installation place number representing coordinate information at which the meter is located.

  Then, the center apparatus 116 identifies the meter 110 based on the identifier of the sensor node 112 in the acquired report information, collects meter reading information of the meter 110 through the sensor node 112, and generates charging information based on the meter reading information. . Then, the charging information is presented to the consumer and collected from the consumer.

  However, when replacing the meter 110, a worker may incorrectly report the identifier (meter number) of the installed meter 110. Then, the identifier of the sensor node 112 previously associated with the incorrect identifier of the meter 110 is registered. For example, it is assumed that the worker erroneously reports the identifier of the meter 110 of the customer home “B” as the report information as the identifier of the meter 110 of the customer home “A”. Then, the meter reading information of the consumer's home "B" is actually read according to the identifier of the sensor node 112 associated with the identifier of the meter 110 of the consumer's home "B" as the meter reading information of the consumer's home "A". It will be collected. Then, billing information based on the meter reading information is presented to the demander of the demander home “A”. That is, billing information will be presented to a consumer different from the actual consumer.

  Therefore, in the present embodiment, the sensor node 112 is appropriately disposed based on the positional relationship between the meter 110 (sensor node 112) and the relay 114. For this reason, the center apparatus 116 determines whether the meter 110 has been installed at the correct position according to the report information.

  Specifically, the data acquisition unit 180 of the center apparatus 116 acquires report information including meter position information and the identifier of the meter 110 from the worker. When the relay position deriving unit 182 receives the report information from the sensor node 112 associated with the identifier of the meter 110, the sensor node 112 associated with the identifier of the meter 110 is actually based on the conduit mapping described above. Indirectly derive relay position information indicating the position of the relay 114 through which the signal passes. The distance deriving unit 184 derives the distance between the meter 110 and the repeater 114 based on the meter position information and the repeater position information. Then, if the derived distance is equal to or more than the predetermined threshold distance, the distance determination unit 186 determines that the meter 110 (sensor node 112) is not associated with the appropriate position.

  For example, as shown in FIG. 5A, when the worker replaces the meter 110 of the demander's home "A", meter position information indicating the position (the demander's home "A") where the meter 110 should be installed , The identifier of the installed meter 110 is associated, and it is assumed that it transmits to the center apparatus 116 as report information. At this time, it is assumed that the worker correctly reports the identifier of the meter 110 of the demander home “A”. The operator can specify the meter position information and the identifier of the meter 110, but can not specify the relay 114 (identifier or position information) with which the sensor node 112 associated with the meter 110 establishes communication.

  Then, when the sensor node 112 associated with the meter 110 transmits meter reading information to the center device 116, in addition to the identifier of the sensor node 112 itself, the identifier of the relay 114 actually passed is also transmitted.

  Therefore, the data acquisition unit 180 can acquire not only the report information but also the identifier of the relay 114 through which the sensor node 112 actually passes. The relay position deriving unit 182 indirectly derives relay position information indicating the position of the relay 114 through which the sensor node 112 actually passes based on the conduit mapping.

  The distance deriving unit 184 derives the distance between the meter 110 and the repeater 114 based on the meter position information included in the report information and the repeater position information derived by the repeater position deriving unit 182. Here, since the position of the meter 110 becomes the customer home “A” based on the meter position information and the position of the relay 114 becomes the consumer home “C” based on the relay position information, the distance deriving unit 184 , Derivation of the distance "D" in FIG. 5 (a).

  Then, the distance determination unit 186 determines that the derived distance, that is, the distance “D” between the consumer “A” and the consumer “C” is equal to or less than the predetermined threshold distance at which wireless communication can be established. It is determined that the (sensor node 112) is associated with the appropriate position. Here, the threshold distance is variable according to the number of hops of the sensor node 112. That is, assuming that the number of hops from sensor node 112 to consumer terminal “A” from customer node “A” is M and the maximum radio wave propagation distance between sensor nodes 112 is Lm, the threshold distance is represented by M × Lm.

  On the other hand, as shown in FIG. 5 (b), meter position information indicating the position (demander's home "A") at which the worker should install the meter 110 with replacement of the meter 110 of demander's home "A". It is assumed that the identifier of the meter 110 installed in the consumer's home "B" is mistakenly associated with and transmitted to the center apparatus 116 as report information.

  Here, when the sensor node 112 associated with the meter 110 transmits meter reading information to the center device 116, in addition to the identifier of the sensor node 112 itself, the identifier of the relay 114 actually passed is also transmitted.

  Therefore, the data acquisition unit 180 can acquire not only the report information but also the identifier of the relay 114 through which the sensor node 112 actually passes. The relay position deriving unit 182 indirectly derives relay position information indicating the position of the relay 114 through which the sensor node 112 actually passes based on the conduit mapping. However, originally, relay station 114 of consumer house “C”, which is closer to consumer house “A”, should be used. In fact, relay station 114 of customer home “E,” which is closer to consumer house “B” The data acquisition unit 180 acquires the identifier of the repeater 114 of the demander's residence "E", and the repeater position derivation unit 182 determines relay location information indicating the customer's residence "E". Derive

  The distance deriving unit 184 derives the distance between the meter 110 and the repeater 114 based on the meter position information included in the report information and the repeater position information derived by the repeater position deriving unit 182. Here, since the position of the meter 110 becomes the customer home “A” based on the meter position information and the position of the relay 114 becomes the consumer home “E” based on the relay position information, the distance deriving unit 184 , Derive the distance "F" in FIG. 5 (b).

  Then, the distance determination unit 186 determines that the derived distance, that is, the distance “F” between the consumer “A” and the consumer “E” can establish a wireless communication with a predetermined threshold distance (eg, M × Lm). Since it is larger than), it is determined that the meter 110 (sensor node 112) is not associated with the appropriate position.

  Thus, based on the positional relationship between the meter 110 (sensor node 112) and the relay 114, it is determined whether or not the sensor node 112 is associated with an appropriate position, and is associated with the appropriate position. If it is not determined, the worker again associates the identifier of the correct meter 110 installed in the consumer “A” with the meter position information, and transmits it to the center apparatus 116 as report information. Thus, the meter 110 (sensor node 112) can be properly disposed.

  Here, although an example in which the identifier of the meter is associated with the meter position information is described as the report information, instead of the identifier of the meter 110, the sensor node 112 corresponding to the meter 110 is An identifier may be associated with meter position information. In this case, the data acquisition unit 180 acquires meter position information and the identifier of the sensor node 112 associated with the installed meter 110, and the repeater position derivation unit 182 is identified by the identifier of the sensor node 112. The sensor node 112 derives relay position information indicating the position of the relay through which the sensor node 112 actually passes. Such a configuration also allows the meter 110 (sensor node 112) to be properly disposed.

(Corresponding to changes in communication environment between sensor nodes)
When the meter 110 is properly arranged, communication between the sensor node 112 and the center apparatus 116 is properly performed in the sensor network system 100. For example, the sensor node 112 transmits information to the center device 116 via another sensor node 112 or a repeater 114. Then, the center device 116 transmits information to the sensor node 112 using the relay through which the sensor node 112 passes.

  FIG. 6 is an explanatory diagram for explaining the positional relationship between the sensor node 112 and the repeater 114. As shown in FIG. Here, for example, it is assumed that the sensor node 112 located at the customer home “A” transmits the meter reading information of the meter 110 associated with the user to the center apparatus 116. In this case, as indicated by the broken arrow in FIG. 6A, the sensor node 112 located in the demander's home "A" hops the sensor node 112 located in the nearby consumer's home "B", Information is transmitted to the center apparatus 116 via the sensor node 112 and the repeater 114 located at the customer home “C”.

  At this time, in the center device 116, the sensor node 112 located at the customer home “A” is any relay 114 among the plurality of relays 114 (here, the relay 114 located at the customer home “C”) Are stored in the center holding unit 172. Then, when transmitting information to the sensor node 112, the center device 116 passes the stored relay 114. That is, the center device 116 transmits information to the sensor node 112 located in the customer home “A” via the repeater 114 located in the customer home “C”.

  Here, the communication environment changes, and as shown in FIG. 6 (b), the sensor node 112 located in the consumer's home "A" is located in the consumer's home "B" where communication could be established so far. It is assumed that the communication with the sensor node 112 becomes unstable.

  Then, the sensor node 112 located at the customer home “A” tries to transmit information by searching for a new sensor node 112 that can establish communication. Then, for example, as indicated by the broken arrow in FIG. 6B, the sensor node 112 located in the customer home “A” is different from the sensor node 112 located in the customer home “B”, a demand The information is transmitted to the center apparatus 116 via the sensor node 112 and the repeater 114 located in the person's home “D”. Thus, the information of the sensor node 112 located at the customer home “A” is properly transmitted to the center device 116.

  However, in the center holding unit 172 of the center device 116, the sensor node 112 located at the customer home “A” passes through the new relay 114 (here, the relay 114 located at the customer home “D”). It may take a long time, for example, 2 to 3 days, to be reflected (the center holding portion 172 is updated). Then, the center apparatus 116 stores the relay 114 stored before the change of the communication environment, that is, until the relay 114 located at the new customer home “D” is reflected in the center apparatus 116, that is, Information is to be distributed to the sensor node 112 via the repeater 114 located at the customer home “C”. In this case, as shown in FIG. 6B, the communication between the sensor node 112 located in the consumer “A” and the sensor node 112 located in the consumer “B” is unstable. Information may not be sent properly. Then, even in the case of closing the meter 110 urgently, the information does not reach the sensor node 112 and the closing is not properly performed.

  So, in this embodiment, it aims at transmitting information to sensor node 112 appropriately using the physical relationship of sensor node 112 and a plurality of relays 114.

  As described above, in the center holding portion 172, the conduit mapping is held, and the position where the meter 110 and the repeater 114 are installed can be specified directly or indirectly by the conduit mapping. Since the meter 110 and the sensor node 112 are associated with each other, the fact that the position at which the meter 110 is set can be identified can also specify the position at which the sensor node 112 associated with the meter 110 is installed. Indicates that. In addition, the center holding unit 172 holds the identifier of the relay 114 through which any sensor node 112 passes, in association with the sensor node 112.

  Then, when the information to an arbitrary sensor node 112 is generated, the information transmission unit 188 of the center apparatus 116 refers to the center holding unit 172, and via the relay 114 associated with the arbitrary sensor node 112. Send information

  Also, when the sensor node 112 can not receive the information, the information transmission unit 188 differs from the relay 114 associated with any sensor node 112 based on the conduit mapping held by the center holding unit 172, Also, it determines another relay 114 closest to any sensor node 112 and transmits information via the other relay 114. Hereinafter, the flow of such processing will be described in detail.

  FIG. 7 is a flowchart for explaining the flow of the information transmission process. When the information to an arbitrary sensor node 112 is generated, the information transmitting unit 188 refers to the center holding unit 172, and the customer home “C” in FIG. 6B associated with the arbitrary sensor node 112. It attempts to transmit information via the located repeater 114 (S200).

  Then, the information transmission unit 188 determines whether the information is normally received by the sensor node 112 (S202). The determination of the normal reception is performed depending on, for example, whether a reception completion response (ACK) is returned from the sensor node 112 in real time or at a predetermined time interval, and the reception completion response is regarded as normal reception when it is returned. However, the present invention is not limited to such a case, and various existing technologies can be applied. Then, if the information is normally received in the sensor node 112 (YES in S202), the information transmission process is ended.

  On the other hand, if the information is not normally received in the sensor node 112 (NO in S202), the information transmitting unit 188 indirectly determines the relay 114 to pass through based on the conduit mapping (S204). Specifically, the information transmission unit 188 is an arbitrary one based on the conduit mapping among the plurality of relays 114 excluding the relays 114 associated with the arbitrary sensor node 112 held in the center holding unit 172. The other repeater 114 closest to the sensor node 112 is extracted. Here, it is assumed that the relay unit 114 located in the demander's house "D" in FIG. 6B is determined.

  Subsequently, the information transmission unit 188 transmits information via the relay unit 114 located at the demander home “D” (S206). Then, the information transmission unit 188 determines again whether or not the information is normally received at the sensor node 112 (S208). Here, if the information is not normally received in the sensor node 112 (NO in S208), the processes from the repeater extraction process S204 are repeated. At this time, the relay 114 determined once is excluded, and the other relays 114 are extracted.

  On the other hand, if the information is normally received in the sensor node 112 (YES in S208), the determined relay 114 is associated with the sensor node 112 and held in the center holding unit 172, and the relay 114 capable of passing is determined. It updates (S210) and the said information transmission process is complete | finished. Thus, information can be properly transmitted to the sensor node 112 through any one of the repeaters 114. Further, in the center holding unit 172, the sensor node 112 is associated with the relay 114 that has newly established communication, and the communication through the relay 114 is maintained unless the communication environment through the new relay 114 becomes unstable. As a result, when the next attempt is made to transmit information, the information can be transmitted to the sensor node 112 quickly and properly.

(Correspondence to change of communication environment about repeater)
In the above, on the assumption that the plurality of relays 114 are normal, the correspondence in the case where the communication environment between the sensor nodes 112 changes has been described using FIGS. 6 and 7. Here, the response in the case where the repeater 114 itself fails or the communication environment around the repeater 114 changes will be described in detail.

  FIG. 8 is an explanatory diagram for explaining the positional relationship between the sensor node 112 and the repeater 114. As shown in FIG. Here, for example, it is assumed that the sensor node 112 located at the customer home “A” transmits the meter reading information of the meter 110 associated with the user to the center apparatus 116. In this case, as indicated by the broken arrows in FIG. 8A, the sensor node 112 located in the consumer home “A” hops the sensor node 112 located in the nearby consumer home “B”, Information is transmitted to the center apparatus 116 via the sensor node 112 and the repeater 114 located at the customer home “C”.

  At this time, as in the case of FIG. 6, in the center device 116, the sensor node 112 located in the customer home “A” becomes any relay 114 (the customer home “C” here) among the plurality of relays 114. It is stored in the center holding unit 172 whether or not the relay unit 114) is located. Then, when transmitting information to the sensor node 112, the center device 116 passes the stored relay 114. That is, the center device 116 transmits information to the sensor node 112 located in the customer home “A” via the repeater 114 located in the customer home “C”.

  Here, when the repeater 114 establishing direct communication with the center apparatus 116 fails or the communication environment around the repeater 114 changes, for example, as shown in FIG. Communication with the repeater 114 located in the customer home “C” becomes unstable, and as a result, information exchange between the sensor node 112 located in the customer home “A” and the center apparatus 116 may become impossible. is there.

  In this case, although it is possible to directly maintain the repeater 114 located in the consumer home “C”, the demander of the consumer home “C” has been away for a long time, and the repeater 114 is associated. The relay 114 may not be able to be directly maintained due to some reasons, such as the meter 110 being closed. Therefore, in the present embodiment, it is an object to appropriately transmit information to the sensor node 112 by using the positional relationship between the relay 114 and the sensor node 112.

  As described above, the center holding unit 172 holds the identifier of the relay 114 via which any sensor node 112 is associated with the sensor node 112. Then, when the information to an arbitrary sensor node 112 is generated, the information transmission unit 188 of the center apparatus 116 refers to the center holding unit 172, and via the relay 114 associated with the arbitrary sensor node 112. Send information

  In addition, when the sensor node 112 can not receive information, the information transmitting unit 188 is, as illustrated in FIG. 6, based on the conduit mapping held by the center holding unit 172, another information node closest to any sensor node 112. The repeater 114 is determined, and information is transmitted via the other repeater 114. Also, in parallel with this, as described below, the information transmission unit 188 determines whether communication with the relay 114 associated with any sensor node 112 is possible, and if communication is not possible, An attempt is made to newly set the repeater 114 in the vicinity thereof. Hereinafter, the flow of the determination process of the normal operation will be described in detail.

  FIG. 9 is a flowchart for explaining the flow of the normal operation determination process, and FIG. 10 is an explanatory diagram for explaining the positional relationship between the sensor node 112 and the relay 114. When the information to an arbitrary sensor node 112 is generated, the information transmitting unit 188 refers to the center holding unit 172, and the customer's home “C” in FIG. 8B associated with the arbitrary sensor node 112. It attempts to transmit information via the located repeater 114 (S300).

  Then, the information transmission unit 188 determines whether the information is normally received by the sensor node 112 (S302). Then, if the information is normally received in the sensor node 112 (YES in S302), the normal operation determination process is ended.

  On the other hand, if the information is not normally received in the sensor node 112 (NO in S302), the information transmission unit 188 performs polling communication to the relay 114 associated with the arbitrary sensor node 112, and It is determined whether or not communication is possible (S304). The determination of the normal operation is performed, for example, based on whether or not communication has been established with a plurality of sensor nodes 112 passing through the relay 114 and the relay 114 in the past, and a plurality of sensor nodes It is assumed that the normal operation is performed when the communication with at least one sensor node 112 of 112 is established. However, the present invention is not limited to such a case, and various existing technologies can be applied. Then, if communication with the relay 114 associated with an arbitrary sensor node 112 is possible (YES in S304), the normal operation determination process is ended.

  On the other hand, if communication with relay 114 associated with an arbitrary sensor node 112 is not possible (NO in S304), information transmission unit 188 is an arbitrary one held in center holding unit 172 based on conduit mapping. The sensor node 112 closest to the relay 114 associated with the sensor node 112 is determined (S306), and the normal operation determination process is ended.

  Here, it is assumed that the sensor node 112 located in the customer home “B” in FIG. 10 is determined. The relay node 114 is newly associated with the sensor node 112 determined as described above after the fact. Although the sensor node 112 closest to the repeater 114 is extracted here, the sensor node 112 located at a communication distance of one or more hops can be set depending on the setting of the communication distance.

  The worker first attempts to directly maintain the repeater 114 which can not communicate. However, if the relay 114 can not be directly maintained due to some reason, such as closure of the meter 110 to which the relay 114 is associated, the worker can use the sensor node 112 determined by the normal operation determination process. The repeater 114 is newly associated (installed).

  By doing this, as shown in FIG. 10, for example, the sensor node 112 located in the customer home “A” is replaced with the repeater 114 not operating normally, and a new one located in the customer home “B” Communication can be established with the center device 116 through the repeater 114, and information can be transmitted to the center device 116, as indicated by the dashed arrow in FIG.

  However, even if a repeater 114 is newly installed, the repeater 114 which can not communicate is not immediately unavailable. For example, in FIG. 10, the cause of the instability of the communication via the repeater 114 located at the customer's home "C" is a failure of the repeater 114 itself or a change in the communication environment around the repeater 114. It can not be easily identified. Assuming that the communication environment around the repeater 114 changes, the repeater 114 itself can still be effectively used.

  Then, the sensor node 112 attempts to communicate with the repeater 114 located at the consumer home “C” where communication with the center apparatus 116 is unstable despite the installation of the repeater 114 newly, The normal operation determination process is executed again, and the processing load is unnecessarily consumed.

  Therefore, when the repeater 114 is newly installed, the information transmission unit 188 removes the repeater 114 located in the customer's home "C" from the communication destination via the newly installed repeater 114, and the software Disable it. Also, if possible, the hardware of the relay 114 located at the customer home “C” is turned off, for example, by powering off.

  In this manner, it is possible to appropriately transmit information to the sensor node 112 while avoiding the relay 114 located at the consumer “C” where communication is unstable becoming unnecessary a communication path.

  Further, as described above, the center holding unit 172 holds the identifier of the relay 114 through which any sensor node 112 passes, in association with the sensor node 112. Here, if the center holding unit 172 holds the relay 114 located in the consumer's home “C”, when transmitting information to the sensor node 112, the consumer's home where the communication is unstable is unnecessary. It will try to communicate with the repeater 114 located at "C".

  Therefore, when the relay unit 114 is invalidated, the information transmission unit 188 causes the invalidated relay unit 114 held in the center holding unit 172 to correspond to the determined sensor node 112. Update all to

  Thus, while avoiding the relay 114 located at the consumer 'C' where the communication is unstable becoming an unnecessary communication path, the sensor node can be detected through the new relay 114 located at the consumer 'B'. It is possible to transmit information to 112 appropriately.

  Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to such embodiments. It will be apparent to those skilled in the art that various changes or modifications can be conceived within the scope of the appended claims, and of course these also fall within the technical scope of the present invention. It is understood.

  In addition, a program that causes a computer to function as the sensor network system 100, the meter 110, the sensor node 112, or the center device 116, or a computer readable flexible disk, an optical magnetic disk, a ROM, or a CD in which the program is recorded. Storage media such as DVD, BD, etc. are also provided. Here, the program refers to data processing means described in any language or description method.

  The processes shown in the present specification do not necessarily have to be processed in chronological order according to the order described in the flowchart, and may include processes in parallel or a subroutine.

  The present invention can be used for a sensor network system and a center device that include a plurality of meters.

100 sensor network system 110 meter 112 sensor node 114 relay 116 center device 172 center holding unit 174 center control unit 180 data acquisition unit 182 relay unit position deriving unit 184 distance deriving unit 186 distance determination unit 188 information transmitting unit

Claims (2)

A sensor node associated with each of a plurality of meters,
A center device that collects information of the meter through the sensor node;
A relay relaying the sensor node and the center apparatus;
A sensor network system comprising
The center device is
A center holding unit that holds a conduit mapping that can specify the location where the sensor node and the repeater are installed, and associates an identifier of the repeater passed by the sensor node with the sensor node;
An information transmitting unit that transmits the information via a relay associated with the arbitrary sensor node when the information to the arbitrary sensor node is generated;
Equipped with
The information transmitting unit differs from the relay associated with the arbitrary sensor node based on the conduit mapping when the information is not received by the arbitrary sensor node, and the arbitrary sensor node A sensor network system that determines another relay close to and transmits the information via the other relay. A sensor node associated with each of a plurality of meters, and a center device collecting information of the meters through a relay connected to the sensor nodes,
A center holding unit that holds a conduit mapping that can specify the location where the sensor node and the repeater are installed, and associates an identifier of the repeater passed by the sensor node with the sensor node;
An information transmitting unit that transmits the information via a relay associated with the arbitrary sensor node when the information to the arbitrary sensor node is generated;
Equipped with
The information transmitting unit differs from the relay associated with the arbitrary sensor node based on the conduit mapping when the information is not received by the arbitrary sensor node, and the arbitrary sensor node The center apparatus which determines the other repeater close to and sends the information via the other repeater.

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