JP7215099B2 - Judgment device and program - Google Patents

Description

The present invention relates to a determination device and program.

Conventionally, there has been proposed a system that collects meter reading information of power consumption measured by a smart meter via a communication network (see Patent Literature 1, for example).

JP 2013-187615 A

In the prior art as shown in Patent Document 1, an RF (Radio Frequency) mesh network system (hereinafter simply referred to as the RF-MESH system) configured by wirelessly connecting a plurality of smart meters in a multi-hop manner is used. may be adopted. However, when performing communication by this RF-MESH method, for example, in the initial stage of transition to the RF-MESH method, when the installation density of RF-MESH method communication devices (for example, smart meters and aggregation devices) is low has a problem that it is difficult to form a communication route by multi-hop connection. Therefore, when the installation density of RF-MESH communication devices is low, the smart meter can be used in addition to the RF-MESH method as a communication means (for example, a communication means using a mobile phone communication network) as an alternative to the RF-MESH method. ) must be provided. In this case, the smart meter needs to be equipped with both the RF-MESH system and other communication means, and there is a problem that the device cost of the smart meter increases. That is, according to the conventional technology, there is a problem that the cost of a smart meter communication system that collects meter reading information on power consumption cannot be reduced. The present invention has been made in view of the above points, and provides a determination device and program capable of reducing the cost of a smart meter communication system.

One aspect of the present invention is a determination target information acquisition unit that acquires identification information for identifying a determination target smart meter, and an installation status of the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit. and an installation status information acquisition unit that acquires installation status information indicating a radio wave that acquires radio wave propagation model information that indicates a radio wave propagation model for the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit. Communication between smart meters installed at positions corresponding to the installation positions of the determination target smart meters indicated by the identification information acquired by the propagation model information acquisition unit and the determination target information acquisition unit, and aggregation with the smart meters A reception quality information acquisition unit that acquires reception quality information indicating the radio wave reception quality of inter-device wireless communication that is communication with the device , transition time information that indicates generation transition time of the inter-device wireless communication, and the installation status Based on the installation status information acquired by the information acquisition unit, the radio wave propagation model information acquired by the radio wave propagation model information acquisition unit, and the reception quality information acquired by the reception quality information acquisition unit, the determination target The type of communication function provided by the smart meter is a communication function that uses the device-to-device wireless communication and a communication function that uses another communication network with a different communication method from the device-to-device wireless communication. and a type selection unit that selects from options including one type and a second type that does not have a communication function that uses the other communication network but has a communication function that uses the inter-device wireless communication. .

Further, in the determination device of one aspect of the present invention, the installation status information includes information indicating the installation status of the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit, in addition to the Information indicating the installation status of smart meters and aggregation devices located around the determination target is included, and the installation status information acquisition unit acquires the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit. and the installation status information including the installation status of the smart meters and the aggregation device located around the determination target.

Further, in the determination device of one aspect of the present invention, the installation status information includes information indicating the future installation status of the smart meter and the aggregation device, and the installation status information acquisition unit acquires the smart The type selection unit acquires the installation status information indicating the installation status of the meter and the aggregation device, and if the communication quality of the wireless communication between the devices at the installation position is equal to or lower than a reference value at the specified time, A third type that has a communication function that uses the other communication network and does not have a communication function that uses the device-to-device wireless communication is selected as the communication function of the smart meter to be determined.

Further, in the determination device of one aspect of the present invention, when the smart meter has both a communication function using the other communication network and a communication function using the inter-device wireless communication, the smart meter, A communication method switching unit that disables the communication function using the other communication network of the smart meter when communication using the device-to-device wireless communication is possible with another smart meter or the aggregation device. further provide.

Further, in the determination device of one aspect of the present invention, the communication method switching unit may include both a communication function using the other communication network and a communication function using the inter-device wireless communication. , if it is predicted that communication between the smart meter and another smart meter or the aggregation device using the device-to-device wireless communication will be impossible, the other communication network of the smart meter Activate the communication function that uses the .

According to one aspect of the present invention, a determination target information acquisition step of acquiring identification information for identifying a determination target smart meter and a determination target smart meter indicated by the identification information acquired in the determination target information acquisition step an installation status information acquisition step of acquiring installation status information indicating the installation status of the meter; and a radio wave propagation model representing a radio wave propagation model of the smart meter to be determined indicated by the identification information acquired in the determination target information acquisition step. A radio wave propagation model information acquiring step for acquiring information; and between smart meters installed at positions corresponding to the installation positions of the determination target smart meters indicated by the identification information acquired in the determination target information acquiring step. A reception quality information acquiring step of acquiring reception quality information indicating the radio wave reception quality of inter-device wireless communication, which is communication between the smart meter and the aggregation device, and a transition time indicating a generation transition time of the inter-device wireless communication. information, the installation status information acquired in the installation status information acquisition step, the radio wave propagation model information acquired in the radio wave propagation model information acquisition step, and the reception quality acquired in the reception quality information acquisition step Based on the information, the type of communication function provided in the smart meter to be determined is determined using a communication function that uses the device-to-device wireless communication and another communication network that uses a communication method different from the device-to-device wireless communication. A type selection selected from options including a first type having both a communication function and a second type having a communication function using the inter-device wireless communication but not the communication function using the other communication network. It is a program for executing steps.

ADVANTAGE OF THE INVENTION According to this invention, the determination apparatus and program which can reduce the cost of a smart meter communication system can be provided.

It is a figure showing an example of an outline of functional composition of a smart meter communications system of a 1st embodiment. It is a figure showing an example of functional composition of a data collection device of this embodiment. It is a figure showing an example of functional composition of a judging device of this embodiment. It is a figure which shows an example of the information memorize|stored in the memory|storage device of this embodiment. It is a figure which shows an example of operation|movement of the determination apparatus of this embodiment. FIG. 10 is a diagram showing an example of update status of a smart meter; It is a figure which shows the modification of operation|movement of the determination apparatus of this embodiment. It is a figure showing an example of functional composition of a judging device of a 2nd embodiment. It is a figure which shows an example of operation|movement of the determination apparatus of this embodiment.

[First embodiment]
An embodiment of a smart meter communication system 1 according to the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing an example of an overview of the functional configuration of a smart meter communication system 1 of the first embodiment.

[Functional configuration of smart meter communication system 1]
The smart meter communication system 1 includes a determination device 10 , a data collection device 20 , a smart meter 30 and an aggregation device 40 . The smart meter communication system 1 is a system that allows the data collection device 20 to collect various types of information transmitted from the smart meter 30 via the mobile phone communication network NT or via the aggregation device 40 .
The smart meter 30 includes a dual communication smart meter 31 , an RF-MESH communication smart meter 32 and a mobile network communication smart meter 33 .

Here, the RF-MESH method is a communication method for transmitting information by mutual communication between a plurality of smart meters 30 and aggregation devices 40 . Communication by the RF-MESH method varies in availability and connection quality depending on the distance between the communicating smart meters 30 and the status of obstacles. For example, when the installation density of the smart meters 30 is relatively low, it is difficult to form a communication path using the RF-MESH method. In addition, when the installation density of the smart meters 30 is relatively high, communication paths using the RF-MESH method are likely to be formed.
On the other hand, in the case of the mobile phone system via the mobile phone network NT, within the coverage area of the mobile phone network NT, regardless of the installation density of the smart meters 30, between the smart meter 30 and the data collection device 20 Communication is possible in
In general, communication using the RF-MESH method has a lower communication cost than communication using the mobile phone method. Therefore, in general, the RF-MESH method is adopted in an area where the installation density of the smart meters 30 is relatively high and where communication paths based on the RF-MESH method are likely to be formed. In addition, in areas where the installation density of the smart meters 30 is relatively low and it is difficult to form a communication path by the RF-MESH system, the mobile phone system is adopted.
The RF-MESH method is an example of a "wireless communication method between devices" that is a communication method between smart meters and a communication method between a smart meter and an aggregation device. Also, the mobile phone system is an example of a "communication system using another communication network" that is different from the wireless communication between devices.

The mobile network communication smart meter 33 can transmit and receive various types of information to and from the data collection device 20 through mobile phone system communication via the mobile phone communication network NT.
The RF-MESH communication smart meter 32 can transmit and receive various types of information to and from the data collection device 20 through RF-MESH communication. The RF-MESH communication smart meter 32 functions as a relay node of the RF-MESH communication network and outputs information collected by itself to the data collection device 20 via the RF-MESH communication network.
The dual communication smart meter 31 can transmit and receive various types of information to and from the data collection device 20 by either the mobile phone system or the RF-MESH system. The dual communication smart meter 31 (dual communication smart meter 31N shown in the figure) that is not connected to the RF-MESH communication network outputs information collected by itself to the data collection device 20 via the mobile phone communication network NT. . A dual communication smart meter 31 (dual communication smart meter 31R shown in the figure) connected to the RF-MESH communication network outputs information collected by itself to the data collection device 20 via the RF-MESH communication network.
Also, the dual communication smart meter 31 transmits and receives control information for forming an RF-MESH communication network with another dual communication smart meter 31 or RF-MESH communication smart meter 32 . Of the dual communication smart meters 31, the dual communication smart meter 31N connected to the mobile phone communication network NT generates reception quality information RI indicating the reception quality of radio waves in the RF-MESH communication network based on the control information. The received reception quality information RI is output to the data collection device 20 via the mobile phone communication network NT. Here, the reception quality of radio waves includes the reception strength of radio waves, the presence or absence of connection for communication by radio waves, or other quantitative values related to radio waves.
These dual communication smart meter 31 and RF-MESH communication smart meter 32 are examples of RF-MESH terminals.

The aggregation device 40 is also called a concentrator, controls and manages the RF-MESH communication network under its control, and relays communication between the RF-MESH terminals and the data collection device 20 .
The data collection device 20 collects various types of information (for example, power consumption meter reading information) from each smart meter 30, and also topology information of the RF-MESH communication network, connection quality of the RF-MESH terminal, RF-MESH It collects and manages RF-MESH management information such as radio reception quality between terminals. The data collection device 20 outputs various collected information to the determination device 10 . Details of the functions of the data collection device 20 will be described with reference to FIG.

[Functional Configuration of Data Collection Device 20]
FIG. 2 is a diagram showing an example of the functional configuration of the data collection device 20 of this embodiment. The data collection device 20 includes a network interface unit 210, a portable system data classification processing unit 220, an RF-MESH system data classification processing unit 230, a data collection processing unit 240, an RF-MESH system management unit 250, and a determination device. and a cooperation unit 260 .

The network interface unit 210 transmits and receives information to and from each smart meter 30 (dual communication smart meter 31 N, mobile network communication smart meter 33 ) and the aggregation device 40 . The network interface unit 210 separates the information according to the mobile phone system and the information according to the RF-MESH system, and outputs the separated information to the mobile system data classification processing unit 220 and the RF-MESH system data classification processing unit 230 .

Portable system data classification processing section 220 classifies the information output from network interface section 210 into meter reading information and RF-MESH management information. Of the separated information, the portable system data classification processing unit 220 outputs the meter reading information to the data collection processing unit 240 and the RF-MESH management information to the RF-MESH system management unit 250, respectively.

The RF-MESH method data classification processing unit 230 classifies the information output from the network interface unit 210 into meter reading information and RF-MESH management information. Of the separated information, the RF-MESH method data classification processing unit 230 outputs the meter reading information to the data collection processing unit 240 and the RF-MESH management information to the RF-MESH method management unit 250, respectively.

The data collection processing unit 240 collects meter reading information and performs processing such as calculation of power consumption. A detailed description of the functions of the data collection processing unit 240 is omitted.

Based on the RF-MESH management information, the RF-MESH system management unit 250 manages the topology of the RF-MESH communication network and the reception quality information RI indicating the radio wave reception quality between RF-MESH terminals.

The determination device cooperation unit 260 outputs the reception quality information RI to the determination device 10 . This reception quality information RI includes a position on the map and information indicating the radio wave reception quality at this position. Next, details of the functions of the determination device 10 will be described with reference to FIG.

[Functional configuration of determination device 10]
FIG. 3 is a diagram showing an example of the functional configuration of the determination device 10 of this embodiment. The determination device 10 includes a determination target information acquisition unit 110 , an installation status information acquisition unit 120 , a radio wave propagation model information acquisition unit 130 , a reception quality information acquisition unit 140 and a type selection unit 150 .

The determination target information acquisition unit 110 acquires a determination target information ID that specifies the smart meter 30 to be determined. Note that this determination target information ID may be information indicating identification information uniquely assigned to each smart meter 30 (for example, device identification information MID), or may be information indicating a customer associated with the smart meter 30. It may be information indicating unique identification information (for example, customer identification information UID). In the following example, it is assumed that the determination target information ID is information indicating the device identification information MID uniquely attached to the smart meter 30 .
Specifically, the determination device 10 is connected to an input device 50 including, for example, a keyboard and a touch panel. Device identification information MID indicating the smart meter 30 to be determined is input to the input device 50 as determination target information ID. The input device 50 outputs the input determination target information ID to the determination device 10 . The determination target information acquisition unit 110 acquires the determination target information ID output by the input device 50 .

Further, the determination target information acquisition section 110 may acquire the designated time information ST from the input device 50 . This designated time information ST is information that designates the time to be judged.

The installation status information acquisition unit 120 identifies the smart meter 30 to be determined based on the determination target information ID acquired by the determination target information acquisition unit 110 . The installation status information acquisition unit 120 acquires installation status information IS regarding the specified smart meter 30 .
The radio wave propagation model information acquisition unit 130 identifies the smart meter 30 to be determined based on the determination target information ID acquired by the determination target information acquisition unit 110 . The radio wave propagation model information acquisition unit 130 acquires radio wave propagation model information PM regarding the identified smart meter 30 .

Specifically, the determination device 10 is connected to the storage device 60, for example. The storage device 60 stores installation status information IS and radio wave propagation model information PM.
FIG. 4 is a diagram showing an example of information stored in the storage device 60 of this embodiment. The storage device 60 stores device identification information MID, position information LC, replacement time information RP, and radio wave propagation model information PM in association with each other.
Among these pieces of information, the installation status information IS includes, for example, location information LC indicating the installation location of the existing smart meter 30 and the aggregation device 40, replacement timing information RP indicating replacement timing, communication method type TY, and the like. Various information is included. The position information LC includes two-dimensional position coordinates or three-dimensional position coordinates of the installation positions of the smart meter 30 and the aggregation device 40 . Among these, the three-dimensional position coordinates include height information such as the altitude of the installation position of the smart meter 30 and the aggregation device 40, sea level, etc. information may be included.

In addition to various information about the existing smart meter 30, the installation status information IS includes various information about the smart meter 30 to be installed and the aggregation device 40, such as the installation position, the scheduled installation time, and the type of communication method. It may be

The installation status information acquisition section 120 searches for the installation status information IS stored in the storage device 60 using the determination target information ID acquired by the determination target information acquisition section 110 as a search key. More specifically, the installation status information acquisition unit 120 searches for the device identification information MID corresponding to the determination target information ID acquired by the determination target information acquisition unit 110, and obtains the installation status linked to the device identification information MID. Extract the information IS. The installation status information acquisition unit 120 acquires the location information LC and the replacement time information RP regarding the smart meter 30 to be determined, which are obtained as the result of this search, as the installation status information IS.
That is, in this example, the installation status information acquisition unit 120 acquires the current installation status and the future installation status of the smart meter 30 (or the aggregation device 40) indicated by the determination target information ID input to the input device 50.

The installation status information acquisition unit 120 also acquires installation status information IS of the smart meters 30 (or the aggregation device 40) installed around the smart meter 30 to be determined. In this case, the installation status information acquisition unit 120 searches for position information LC indicating positions around the position information LC of the smart meter 30 to be determined. The installation status information acquisition unit 120 acquires the device identification information MID and the installation status information IS for the smart meter 30 (or the aggregation device 40) linked to the location information LC obtained as a result of the search.

Returning to FIG. 3, the radio wave propagation model information PM includes radio wave propagation corresponding to the density of the smart meter 30 and the aggregation device 40 (for example, Urban/Suburban/Rural), or the smart meter 30 and the aggregation device 40 are installed. It contains information on multiple models of radio wave propagation according to the type of area (for example, detached house area/multi-family housing area).
The radio wave propagation model information acquisition unit 130 acquires the radio wave propagation model information PM at the location where the smart meter 30 (or the aggregation device 40) corresponding to the determination target information ID acquired by the determination target information acquisition unit 110 is installed. . That is, the radio wave propagation model information acquisition unit 130 acquires the radio wave propagation model information PM corresponding to the installation status information IS.
In this example, the radio wave propagation model information PM is described as being linked to the device identification information MID and stored in the storage device 60 for each smart meter 30 (or aggregation device 40), but this is not the only option. can't For example, the radio wave propagation model information PM is linked to the installation density or area of the smart meter 30 (or the aggregation device 40) (for example, as a table separate from the table in which the installation status information IS is stored), It may be stored in the storage device 60 . In this case, the radio wave propagation model information acquisition unit 130 determines the installation density or area type of the smart meters 30 (or the aggregation device 40) based on the installation status information IS acquired by the installation status information acquisition unit 120, The radio wave propagation model information PM associated with the determined result is acquired from the storage device 60 .

The reception quality information acquisition unit 140 receives radio wave reception quality of wireless communication between devices (RF-MESH method communication) around the installation position of the smart meter 30 indicated by the determination target information ID acquired by the determination target information acquisition unit 110. Acquire the quality information RI. Here, inter-device wireless communication (RF-MESH system communication) is communication between the smart meters 30 and communication between the smart meter 30 and the aggregation device 40 .

Specifically, the determination device 10 is connected to the data collection device 20 . As described above, the data collection device 20 outputs reception quality information RI. This reception quality information RI includes information indicating the communication quality of communication between the smart meters 30 and communication between the smart meter 30 and the aggregation device 40 .
In the following description, the smart meter 30 and the aggregation device 40 that perform inter-device wireless communication are collectively referred to as "inter-device wireless communication nodes" or simply "nodes." In other words, the reception quality information RI includes information indicating communication quality between nodes.
The reception quality information acquisition section 140 searches for the reception quality information RI using the determination target information ID acquired by the determination target information acquisition section 110 as a search key. Reception quality information acquisition section 140 acquires information indicating communication quality obtained as a result of the search as reception quality information RI.
That is, in this example, the reception quality information acquiring unit 140 acquires information indicating the radio wave reception quality around the smart meter 30 to be determined, which is input to the input device 50 .

The type selection unit 150 selects the installation status information IS acquired by the installation status information acquisition unit 120, the radio wave propagation model information PM acquired by the radio wave propagation model information acquisition unit 130, and the reception quality information acquired by the reception quality information acquisition unit 140. Based on the RI, the type of communication function provided in the smart meter 30 to be determined is selected.

The types of communication functions selected by the type selection unit 150 include the dual communication smart meter 31 (first type), the RF-MESH communication smart meter 32 (second type), and the mobile network communication smart meter 33 (third type). is included.
Here, the dual communication smart meter 31 has both a communication function using the mobile phone communication network NT and a communication function using inter-device wireless communication (RF-MESH method communication) among the smart meters 30. It is a smart meter 30 .
The RF-MESH communication smart meter 32 is a smart meter 30 that does not have a communication function that uses the mobile phone communication network NT but has a communication function that uses inter-device wireless communication (RF-MESH method communication). is.
The mobile network communication smart meter 33 is a smart meter 30 that has a communication function that uses the mobile phone communication network NT but does not have a communication function that uses inter-device wireless communication (RF-MESH method communication). is.

In other words, the type selection unit 150 selects the type of communication function of the smart meter 30 to be determined from options including at least the dual communication smart meter 31 and the RF-MESH communication smart meter 32 .
Further, the type selection unit 150 may select the type of communication function provided in the smart meter 30 to be determined from options including the mobile network communication smart meter 33 .

The type selection unit 150 outputs the selected communication function type to the output device 70 as a selection result RS.
The output device 70 includes, for example, a liquid crystal display and a printer, and outputs the selection result RS output from the determination device 10 to an image, paper medium, or the like. Also, the output device 70 may have a communication function. In this case, the output device 70 transmits the selection result RS to other devices.

[Operation of determination device 10]
Next, an example of the operation of the determination device 10 of this embodiment will be described with reference to FIG.
FIG. 5 is a diagram showing an example of the operation of the determination device 10 of this embodiment.

(Step S<b>10 ) The determination target information acquisition unit 110 acquires a determination target information ID specifying the smart meter 30 to be determined from the input device 50 . Further, the determination target information acquisition unit 110 acquires the specified time information ST from the input device 50 .
The determination target information acquiring section 110 outputs the acquired determination target information ID and the specified time information ST to the installation status information acquiring section 120 . The installation status information acquisition unit 120 searches the storage device 60 based on the determination target information ID, and obtains the installation status information IS about the position of the smart meter 30 to be determined and the smart meters 30 and the aggregation device 40 around the position. get. This installation status information IS includes location information LC and replacement time information RP of the smart meter 30 and the aggregation device 40 .

(Step S20) The radio wave propagation model information acquisition unit 130 acquires the radio wave propagation model information PM indicating the radio wave propagation model at the installation position of the smart meter 30 to be determined based on the determination target information ID acquired in step S10. .

(Step S30) The reception quality information acquisition unit 140 acquires the reception quality information RI indicating the radio wave reception quality of the existing smart meter 30 from the data collection device 20 based on the determination target information ID acquired in step S10.

(Step S40) Based on the installation status information IS, the radio wave propagation model information PM, and the reception quality information RI acquired in steps S10 to S30, the type selection unit 150 selects the RF- A future connection probability (future connection probability FR) by the MESH method is calculated.
As a specific example, the type selection unit 150 calculates the future connection probability FR at the specified time based on the installation status information IS. This specified time is supplied from the input device 50 as specified time information ST, for example. More specifically, the type selection unit 150 selects the smart meter 30 (and the aggregation device 40 ) is installed. Based on the determined future installation status of the smart meter 30 (and the aggregation device 40), the type selection unit 150 estimates the path configuration of the communication path CR for wireless communication between devices at each period after the specified period. Based on the route configuration of the estimated communication route CR, the type selection unit 150 determines the probability that the communication route CR for device-to-device wireless communication can be configured between the smart meter 30 to be determined and the aggregation device 40, that is, the future connection probability. Calculate FR. Here, in the communication route CR of wireless communication between devices, there are cases where the smart meter 30 to be judged reaches the aggregation device 40 via another smart meter 30, and direct aggregation from the smart meter 30 to be judged. It may reach device 40 .
Further, in calculating the future connection probability FR described above, the type selection unit 150 can also correct the future connection probability FR based on the reception quality information RI. As a specific example, the type selection unit 150 performs a correction to increase the calculated future connection probability FR when the communication route CR includes a route that is actually connected for communication at the present time. Further, if the communication route CR includes a route that is not currently connected for communication, the type selection unit 150 performs correction to lower the calculated future connection probability FR.

(Step S50) The type selection unit 150 compares the future connection probability FR of the RF-MESH method calculated in step S40 with the reference value of the future connection probability FR. When the type selection unit 150 determines that the future connection probability FR is not equal to or greater than the reference value (step S50; NO), the process proceeds to step S60. If the type selection unit 150 determines that the future connection probability FR is equal to or greater than the reference value (step S50; YES), the process proceeds to step S70.

That is, the type selection unit 150 selects the type of communication function provided in the smart meter 30 to be determined based on the designated time.

(Step S60) The type selection unit 150 determines that the type of the smart meter 30 to be determined is the mobile network communication smart meter 33 (third type), and terminates the series of processes.

That is, after the specified time indicated by the specified time information ST, if the connection probability of wireless communication between devices (RF-MESH method communication) at the installation position is equal to or less than the reference value, the type selection unit 150 selects the mobile network communication smart The meter 33 (third type) is selected as the communication function of the smart meter 30 to be determined.

(Step S70) The type selection unit 150 selects the smart meter 30 to be determined based on the installation status information IS, the radio wave propagation model information PM, and the reception quality information RI acquired in steps S10 to S30. , the current connection probability (immediate connection probability IR) by the RF-MESH method at the installation position is calculated.
Note that the specific procedure for calculating the immediate connection probability IR is the same as the procedure for calculating the future connection probability FR in step S40 described above, so description thereof will be omitted.

(Step S80) The type selection unit 150 compares the immediate connection probability IR of the RF-MESH method calculated in step S70 with the reference value of the immediate connection probability IR. If type selection unit 150 determines that immediate connection probability IR is not equal to or greater than the reference value (step S80; NO), the process proceeds to step S90. If type selection unit 150 determines that immediate connection probability IR is equal to or greater than the reference value (step S80; YES), the process proceeds to step S100.

(Step S90) The type selection unit 150 determines that the type of the smart meter 30 to be determined is the dual communication smart meter 31 (first type), and terminates the series of processes.

(Step S100) The type selection unit 150 determines that the type of the smart meter 30 to be determined is the RF-MESH communication smart meter 32 (second type), and terminates the series of processes.

[Summary of the first embodiment]
As described above, the determination device 10 of this embodiment includes the type selection unit 150 . The type selection unit 150 selects the type of communication function provided in the smart meter 30 to be determined based on the installation status information IS, the radio wave propagation model information PM, and the reception quality information RI.
As described above, the smart meter 30 is classified into at least three types, the dual communication smart meter 31, the RF-MESH communication smart meter 32, and the mobile network communication smart meter 33, depending on the communication function.
In general, the mobile phone system has higher communication costs than the RF-MESH system. Therefore, in an environment where an RF-MESH communication network is constructed, it is desirable to perform communication by the RF-MESH method from the viewpoint of communication costs. On the other hand, in an environment in which no RF-MESH communication network has been constructed, there is no choice but to use the mobile phone system for communication even if the communication cost is relatively high.
Here, the dual communication smart meter 31 communicates by the mobile phone system in an environment where the RF-MESH communication network is not built, and communicates by the RF-MESH system in the environment where the RF-MESH communication network is built. It can be performed. In other words, the dual communication smart meter 31 can communicate even in an environment where an RF-MESH communication network is not built, and can switch to the RF-MESH system in an environment where an RF-MESH communication network is built. communication cost can be reduced. On the other hand, the dual communication smart meter 31 has both a communication function based on the mobile phone system and a communication function based on the RF-MESH system. configuration is complicated, and the price of the device is relatively high.
The RF-MESH communication smart meter 32 has a relatively simple device configuration and a relatively low price, but cannot communicate in an environment where an RF-MESH communication network is not established.
In addition, the mobile network communication smart meter 33 has a relatively simple device configuration and is relatively inexpensive, but even in an environment where an RF-MESH communication network is built, the communication cost is relatively low. Communication is not possible without a highly effective mobile phone system.
In view of the advantages and disadvantages of the dual communication smart meter 31, the RF-MESH communication smart meter 32, and the mobile network communication smart meter 33, the determination device 10 of the present embodiment performs a type of communication according to the construction status of the RF-MESH communication network. Select a smart meter 30 with a scheme. Therefore, according to the determination device 10 of the present embodiment, it is possible to further reduce the cost required for building and operating the RF-MESH communication network using the smart meter 30 .

FIG. 6 is a diagram showing an example of update status of the smart meter 30. As shown in FIG. In the figure, the horizontal axis indicates time t, and the vertical axis indicates the number of smart meters 30 introduced (installed). In this example, the first generation G1 smart meter 30 communicates using both the mobile phone system and the RF-MESH system. At time t2, the shift from the first generation G1 to the second generation G2 is started. The mobile phone system and the next-generation RF-MESH system are used together for communication of the smart meter 30 of the second generation G2. Here, there is no compatibility between the first generation G1 RF-MESH method and the second generation G2 next-generation RF-MESH method. Therefore, after the transition to the second generation G2, communication by the RF-MESH method of the first generation G1 cannot be performed.
Further, in a generation (0th generation G0 not shown) prior to the first generation G1, a so-called mechanical watt-hour meter is installed, and information is collected from the smart meter 30 wirelessly or by wire. do not have.

From time t0 to time t1 (that is, the initial stage of the start of the first generation G1), the number of smart meters 30 that can communicate by the RF-MESH method is relatively small, so the communication network by the RF-MESH method is sufficiently constructed. It has not been.
In this way, in the initial stage of the first generation G1 (for example, between time t0 and time t1), the density of RF-MESH communication network nodes (for example, smart meters 30 and aggregation devices 40) in a certain area is , may not increase to the extent that an RF-MESH communication network can be constructed. In this area, the smart meter 30 needs to communicate using a mobile phone system.
Also, in the middle stage of the first generation G1 (for example, between time t1 and time t2), the node density of the RF-MESH communication network in this area may increase to the extent that the RF-MESH communication network can be constructed. be. In this area, the smart meter 30 can communicate using the RF-MESH method.
In other words, in the initial stage of the introduction of the RF-MESH method, even if it is an area where there is no choice but to communicate by the mobile phone method, it is possible to communicate by the RF-MESH method in this area after the middle stage. may become In this case, the determination device 10 selects the dual communication smart meter 31 as the smart meter 30 to be installed.
According to the determination device 10 of the present embodiment, it is possible to secure a communication path between the smart meter 30 and the data collection device 20 even when the RF-MESH communication network is not sufficiently established.

Further, as described above, when the RF-MESH communication network is sufficiently established (for example, between time t1 and time t2), the smart meter 30 can communicate by the RF-MESH method. That is, when the RF-MESH communication network is sufficiently established (for example, between time t1 and time t2), the smart meter 30 can perform communication by the RF-MESH method without performing communication by the mobile phone method. is possible. According to the determination device 10 of the present embodiment, the RF-MESH communication smart meter 32 is selected as the smart meter 30 to be installed in the middle stage of the first generation G1 (for example, between time t1 and time t2). Therefore, according to the determination device 10 of the present embodiment, device cost can be further reduced compared to the case where the dual communication smart meter 31 is selected.

Further, depending on the area where the smart meter 30 is installed, even if the RF-MESH communication network is sufficiently established in other areas (for example, between time t1 and time t2), the RF-MESH method It may be difficult to secure a communication route by For example, the number of installed smart meters 30 may not be sufficient in areas such as mountainous areas and islands where the density of smart meters 30 is low compared to areas such as urban areas where the density of smart meters 30 is high. In such an area, it will be difficult to secure a communication path using the RF-MESH method in the future. Based on the future connection probability FR, the determination device 10 of the present embodiment determines that the dual communication smart Instead of the meter 31, the mobile network communication smart meter 33 is selected as the smart meter 30 to be installed. Therefore, according to the determination device 10 of the present embodiment, the device cost can be further reduced compared to the case where the dual communication smart meter 31 is selected.

As described above, there is no compatibility between the first generation G1 RF-MESH method and the second generation G2 next-generation RF-MESH method. Therefore, even at the beginning of the shift from the first generation G1 to the second generation G2 (time t3 to time t4) shown in FIG. A similar situation arises. In other words, in the early stage of introduction of the next-generation RF-MESH system of the second generation G2 (time t3 to time t4), even if it is an area where communication is forced to be performed by the mobile phone system, from the middle stage onwards, In this area, it may become possible to perform communication by the next-generation RF-MESH method. In this case, the determination device 10 selects the dual communication smart meter 31 as the smart meter 30 to be installed.

[Modification]
FIG. 7 is a diagram showing a modification of the operation of the determination device 10 of this embodiment. The same reference numerals are given to the same configurations and operations as those of the above-described embodiment, and the description thereof will be omitted. This modification differs from the above-described embodiment in that the determination device 10 selects the type of communication function of the smart meter 30 based on the generation transition timing of the communication method of the smart meter 30 . More specifically, this modification differs from the above-described embodiment in that steps S210 to S230 are added.

(Step S210) The type selection unit 150 acquires transition time information UT. This transition time information UT indicates the future generation transition timing of the smart meter 30 (for example, the transition timing from the first generation G1 shown in FIG. 6 to the second generation G2).
(Step S220) The type selection unit 150 selects the planned installation position of the smart meter 30 to be determined based on the generation transition timing indicated by the transition timing information UT (for example, the transition timing from the first generation G1 to the second generation G2). and the surrounding area, the probability of connection by the RF-MESH method after the transition period (connection probability at transition) is calculated.
(Step S230) The type selection unit 150 determines whether or not the transition connection probability calculated in step S220 is equal to or greater than a predetermined reference value. If the type selection unit 150 determines that the migration connection probability is equal to or greater than the predetermined reference value (step S230; YES), the process proceeds to step S100, and the RF-MESH communication smart meter 32 is selected. End a series of processes. If the type selection unit 150 determines that the transition connection probability is not equal to or greater than the predetermined reference value (step S230; NO), the process proceeds to step S90, selects the dual communication smart meter 31, and end the processing of

As an example, when the next generation RF-MESH method is adopted in the second generation G2, even in areas where the connection probability by the RF-MESH method in the first generation G1 is sufficiently high, the first generation G1 to the second generation The probability of connection by the RF-MESH method may decrease with the generation shift to G2. In this case, if the RF-MESH communication smart meter 32 is installed when shifting from the first generation G1 to the second generation G2, communication by the RF-MESH communication smart meter 32 becomes impossible when shifting to the second generation G2. In this case, in order to secure the communication path from the smart meter 30 to the data collection device 20, the smart meter 30 must be updated again (for example, re-installed) when shifting from the first generation G1 to the second generation G2. Therefore, there arises a problem that the cost of the device increases.

As an example, in the period (time t2 to time t3) immediately before the shift from the first generation G1 to the second generation G2 shown in FIG. However, in the final stage of transition from the first generation G1 to the second generation G2 (time t5 to time t6), a situation arises in which communication by the RF-MESH method of the first generation G1 cannot be performed.
In this case, even if communication by the first generation G1 RF-MESH method is possible at the time (time t2 to time t3) immediately before the transition from the first generation G1 to the second generation G2, the determination device 10 The dual communication smart meter 31 is selected as the smart meter 30 to be installed. In this case, after the transition to the second generation G2, the dual communication smart meter 31 secures a communication path by performing communication using the mobile phone system.

According to the determination device 10 of this modified example, the type of the smart meter 30 is determined based on the future transition time. According to the determination device 10, when the probability of connection by the RF-MESH method decreases in the future transition period, by selecting the dual communication smart meter 31 or the mobile network communication smart meter 33, the first generation G1 A communication path can be secured even after the transition to the next generation (for example, the second generation G2) in which an incompatible device-to-device communication method is adopted.

Further, when the type selection unit 150 of the determination device 10 determines in the above-described step S230 that the transition connection probability is not equal to or greater than the predetermined reference value (step S230; NO), the dual communication smart meter 31 is replaced with the , the mobile network communication smart meter 33 may be selected. In other words, when the probability of connection by the RF-MESH system decreases in the transition period in the future, the determination device 10 selects the mobile network communication smart meter 33 that does not have the communication function by the RF-MESH system. According to the determination device 10 configured in this way, the device cost is reduced compared to the case of selecting the dual communication smart meter 31 while securing the communication path even after the transition to the second generation G2 is performed. can be reduced.

[Second embodiment]
Next, the determination device 10a according to the second embodiment will be described. The same reference numerals are given to the same configurations and operations as those of the above-described embodiment and its modification, and the description thereof will be omitted. A determination device 10a according to the second embodiment differs from the above-described embodiments and their modifications in that a communication method switching unit 160 is provided.

FIG. 8 is a diagram showing an example of the functional configuration of the determination device 10a of the second embodiment. The communication method switching unit 160 performs control to switch the communication method of the dual communication smart meter 31 between the mobile phone method and the RF-MESH method. Specifically, the determination device 10 a is connected to the control device 80 . Communication method switching section 160 outputs switching information CMD to control device 80 . This switching information CMD includes control information indicating which of the mobile phone system and the RF-MESH system should be selected as the communication system of the dual communication smart meter 31 . The control device 80 outputs switching information CMD to the dual communication smart meter 31 through communication with the dual communication smart meter 31 .
The dual communication smart meter 31 switches the communication system between the mobile phone system and the RF-MESH system based on the switching information CMD output by the determination device 10a via the control device 80. FIG.

FIG. 9 is a diagram showing an example of the operation of the determination device 10a of this embodiment. Note that when a plurality of dual communication smart meters 31 are installed in the smart meter communication system 1 , the determination device 10 a performs the following processing for each dual communication smart meter 31 .

(Step S310) The communication method switching unit 160 acquires RF-MESH information output by the dual communication smart meter 31 to be determined. In this example, RF-MESH information is collected by the data collection device 20 from each smart meter 30 along with reception quality information RI. The RF-MESH information includes information indicating whether the dual communication smart meter 31 uses the mobile phone system or the RF-MESH system for communication.

(Step S320) Based on the RF-MESH information acquired in step S310, the communication method switching unit 160 determines whether or not the dual communication smart meter 31 to be determined is communicating by the mobile phone method. When the communication method switching unit 160 determines that the dual communication smart meter 31 to be determined is communicating by the mobile phone method (step S320; YES), the process proceeds to step S330. When the communication method switching unit 160 determines that the dual communication smart meter 31 to be determined is not communicating by the mobile phone method (that is, is communicating by the RF-MESH method) (step S320; NO), advances the process to step S360.

(Step S330) Based on the reception quality information RI, the communication method switching unit 160 determines whether or not the current connection quality of the dual communication smart meter 31 to be determined by the RF-MESH method is equal to or higher than a predetermined reference value. judge. When the communication system switching unit 160 determines that the connection quality by the RF-MESH system is equal to or higher than the predetermined reference value (step S330; YES), the process proceeds to step S340. When the communication system switching unit 160 determines that the connection quality by the RF-MESH system is not equal to or higher than the predetermined reference value (step S330; NO), the process proceeds to step S350.

(Step S340) The communication method switching unit 160 transmits switching information CMD for switching the communication method from the mobile phone method to the RF-MESH method to the dual communication smart meter 31 to be determined via the control device 80, and performs processing. finish. That is, the communication method switching unit 160 disables the communication function of the smart meter 30 that uses the mobile phone communication network NT.
(Step S350) The communication method switching unit 160 terminates the process without switching the communication method.

(Step S360) Based on the reception quality information RI, the communication method switching unit 160 determines whether or not the current connection quality of the dual communication smart meter 31 to be determined by the RF-MESH method is equal to or lower than a predetermined reference value. judge. If the communication system switching unit 160 determines that the connection quality by the RF-MESH system is equal to or lower than the predetermined reference value (step S360; YES), the process proceeds to step S410. When the communication system switching unit 160 determines that the connection quality by the RF-MESH system is not equal to or lower than the predetermined reference value (step S360; NO), the process proceeds to step S370.

(Step S370) Based on the installation status information IS, the communication method switching unit 160 determines the installation position of the dual communication smart meter 31 to be determined and the location of the smart meter 30 or the aggregation device 40 installed in the surrounding area. And extract the installation time.
(Step S380) Based on the installation status information IS, the communication method switching unit 160 extracts the installation position of the dual communication smart meter 31 to be determined and the shift timing of the smart meters 30 installed in the surrounding area.
(Step S390) The communication method switching unit 160 calculates the connection probability by the RF-MESH method after a predetermined period of time at the installation position of the dual communication smart meter 31 to be determined.
(Step S400) The communication method switching unit 160 determines whether or not the probability of connection by the RF-MESH method after the elapse of a predetermined period is equal to or less than a predetermined reference value. If the communication system switching unit 160 determines that the probability of connection by the RF-MESH system after the lapse of the predetermined period is equal to or less than the predetermined reference value (step S400; YES), the process proceeds to step S410. If the communication method switching unit 160 determines that the probability of connection by the RF-MESH method after the elapse of the predetermined period is not equal to or lower than the predetermined reference value (step S400; NO), the process proceeds to step S420.

(Step S410) The communication method switching unit 160 transmits switching information CMD for switching the communication method from the RF-MESH method to the mobile phone method to the dual communication smart meter 31 to be determined via the control device 80, and performs processing. finish.
(Step S420) The communication method switching unit 160 terminates the process without switching the communication method.

[Summary of the second embodiment]
As described above, the determination device 10a of this embodiment includes the communication method switching unit 160. FIG. This communication method switching unit 160 is a smart When communication using inter-device wireless communication (for example, RF-MESH method) is possible between the meter 30 and another smart meter 30 or aggregation device 40, the mobile phone communication network NT of the smart meter 30 Disable the communication function to be used.

The determination device 10a of the present embodiment changes the communication method of the dual communication smart meter 31, which is arranged before the RF-MESH communication network is constructed, to the mobile phone method after the RF-MESH communication network is constructed. to the RF-MESH method. According to the determination device 10a configured in this way, after the RF-MESH communication network is constructed, communication can be performed by the RF-MESH method with relatively low communication costs. Therefore, according to the determination device 10a configured in this manner, communication costs can be reduced.

In addition, when the smart meter 30 has both a communication function using the mobile phone communication network NT and a communication function using wireless communication between devices (for example, the RF-MESH method), the communication method switching unit 160 If it is predicted that communication using device-to-device wireless communication (for example, RF-MESH method) between the smart meter 30 and another smart meter 30 or aggregation device 40 will become impossible in the future, A communication function using the mobile phone communication network NT of the smart meter 30 may be activated.

Although the embodiments of the present invention have been described above in detail with reference to the drawings, the specific configuration is not limited to these embodiments, and modifications can be made as appropriate without departing from the scope of the present invention. can. Moreover, each embodiment described above can be appropriately combined without departing from the gist of the present invention.

Each of the devices described above has a computer inside. The process of each process of each device described above is stored in a computer-readable recording medium in the form of a program, and the above process is performed by reading and executing this program by a computer. Here, the computer-readable recording medium refers to magnetic disks, magneto-optical disks, CD-ROMs, DVD-ROMs, semiconductor memories, and the like. Alternatively, the computer program may be distributed to a computer via a communication line, and the computer receiving the distribution may execute the program.

Further, the program may be for realizing part of the functions described above.
Further, it may be a so-called difference file (difference program) that can realize the above-described functions in combination with a program already recorded in the computer system.

Reference Signs List 1 smart meter communication system 10, 10a determination device 110 determination target information acquisition unit 120 installation status information acquisition unit 130 radio wave propagation model information acquisition unit 140 reception quality information acquisition unit 150 type Selection unit 160 Communication method switching unit 20 Data collection device 210 Network interface unit 220 Portable system data classification processing unit 230 RF-MESH system data classification processing unit 240 Data collection processing unit 250 ... RF-MESH method management unit, 260 ... determination device cooperation unit, 30 ... smart meter, 31 ... dual communication smart meter, 32 ... RF-MESH communication smart meter, 33 ... mobile network communication smart meter, 40 ... aggregation device, 50 Input device 60 Storage device 70 Output device NT Mobile phone communication network IS Installation status information PM Radio wave propagation model information RI Reception quality information CMD Switching information

Claims (6)

a determination target information acquisition unit that acquires identification information that identifies a smart meter to be determined;
an installation status information acquisition unit for acquiring installation status information indicating an installation status of the smart meter to be determined indicated by the identification information acquired by the determination target information acquisition unit;
a radio wave propagation model information acquisition unit for acquiring radio wave propagation model information indicating a radio wave propagation model for the smart meter to be determined indicated by the identification information acquired by the determination target information acquisition unit;
Communication between smart meters installed at positions corresponding to the installation positions of the smart meters to be determined indicated by the identification information acquired by the determination target information acquisition unit and communication between the smart meters and the aggregation device a reception quality information acquisition unit that acquires reception quality information indicating the radio wave reception quality of wireless communication between certain devices;
transition time information indicating a generation transition time of the inter-device wireless communication; the installation status information acquired by the installation status information acquisition unit; the radio wave propagation model information acquired by the radio wave propagation model information acquisition unit; Based on the reception quality information acquired by the quality information acquisition unit, the type of communication function provided in the smart meter to be determined is determined to be a communication function that uses the inter-device wireless communication and the inter-device wireless communication is communication. A first type that has a communication function that uses another communication network with a different method, and a second type that has a communication function that uses wireless communication between devices without having a communication function that uses the other communication network. a type selection unit that selects from options including a type;
A determination device comprising: The installation status information includes, in addition to information indicating the installation status of the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit, smart meters and aggregation devices located around the determination target. contains information indicating the installation status of the
The installation status information acquisition unit
Acquiring the installation status information including the installation status of the determination target smart meter indicated by the identification information acquired by the determination target information acquisition unit, and the installation status of smart meters and aggregation devices located around the determination target. The determination device according to claim 1. The installation status information includes information indicating the future installation status of the smart meter and the aggregation device,
The installation status information acquisition unit
Acquiring the installation status information indicating the installation status of smart meters and aggregation devices at a specified time in the future;
The type selection unit is
When the communication quality of the wireless communication between devices at the installation position is equal to or lower than a reference value at the specified time, the communication function using the wireless communication between devices is provided, and the communication function uses the other communication network. The determination device according to claim 1 or 2 , wherein the communication function of the smart meter to be determined is selected as a third type that does not include Between the smart meter and the other smart meter or the aggregation device when the smart meter has both the communication function using the other communication network and the communication function using the inter-device wireless communication 4. The smart meter according to any one of claims 1 to 3 , further comprising a communication method switching unit that disables a communication function that uses the other communication network of the smart meter when communication using the device-to-device wireless communication is possible. or the determination device according to claim 1. The communication method switching unit
Between the smart meter and the other smart meter or the aggregation device when the smart meter has both the communication function using the other communication network and the communication function using the inter-device wireless communication The determination device according to claim 4 , wherein when it is predicted that communication using the device-to-device wireless communication will become impossible, the communication function of the smart meter that uses the other communication network is enabled. a determination target information acquiring step of acquiring identification information for identifying a smart meter to be determined in a computer;
an installation status information acquisition step of acquiring installation status information indicating an installation status of the smart meter to be determined indicated by the identification information acquired in the determination target information acquisition step;
a radio wave propagation model information acquiring step of acquiring radio wave propagation model information indicating a radio wave propagation model for the smart meter to be determined indicated by the identification information acquired in the determination target information acquiring step;
Communication between smart meters installed at positions corresponding to the installation positions of the smart meters to be determined indicated by the identification information acquired in the determination target information acquisition step, and communication between the smart meters and the aggregation device a reception quality information acquisition step of acquiring reception quality information indicating the radio wave reception quality of wireless communication between devices;
transition time information indicating a generation transition time of the inter-device wireless communication; the installation status information acquired in the installation status information acquisition step; and the radio wave propagation model information acquired in the radio wave propagation model information acquisition step; Based on the reception quality information acquired in the reception quality information acquiring step, the types of communication functions provided in the smart meter to be determined are determined to be a communication function using the inter-device wireless communication and the inter-device wireless communication. A first type that has both a communication function that uses another communication network with a different communication method, and a communication function that uses wireless communication between devices without having a communication function that uses the other communication network a type selection step of selecting from options including a second type provided;
program to run the

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