JP6958103B2 - Parent device and communication control method - Google Patents

Description

The present invention relates to a parent device and a communication control method.

In recent years, electric power information communication systems have been developed that measure the amount of electric power consumed at home and at work for the purpose of saving electricity and transmit it to a server of an electric power company or the like. For example, Patent Document 1 (Japanese Unexamined Patent Publication No. 2006-67557) discloses the following techniques.

That is, in the communication route construction method, a communication route between the parent communication terminal and the child communication terminal in a communication network including a parent communication terminal and a plurality of child communication terminals is constructed, and the communication terminal is used. , The communication quality notification step of transmitting a notification communication packet including communication quality information indicating the communication quality in the communication route between the own communication terminal and the parent communication terminal to the communication network by broadcast communication, and the communication of the child. When the terminal receives the notification communication packet, the communication quality from the communication terminal of the source that transmitted the notification communication packet to the own communication terminal is acquired, and the transmission source that transmits the notification communication packet from the own communication terminal. The communication quality acquisition step of acquiring the communication quality to the communication terminal, the bidirectional communication quality acquired by the child communication terminal receiving the notification communication packet in the communication quality acquisition step, and the received notification communication. The communication quality between the parent communication terminal and the own communication terminal is calculated based on the communication quality information included in the packet, and only when the calculated communication quality satisfies a predetermined condition, the parent communication terminal It includes a communication route construction step for constructing a communication route between a communication terminal and a self-communication terminal.

Japanese Unexamined Patent Publication No. 2006-67557

G3-PLC® Alliance, "Narrowband OFDM PLC specializations for G3-PLC networks", G3-PLC Alliance, October 2014

In the communication network described in Patent Document 1, for example, a plurality of master units may be provided. In such a communication network, the master unit manages a plurality of slave units, and periodically acquires power information from the slave units managed by the master unit. For example, if one of the plurality of master units fails, the slave unit under the control of the failed master unit tries to enter the control of the other master unit. However, if there is an upper limit to the number of slave units that can be managed by the master unit, other master units may not be able to manage the slave units that are going to be under their control. In such a situation, the power information from the slave unit that is not under the control of the master unit is lost, which is not preferable.

The present invention has been made to solve the above-mentioned problems, and an object of the present invention is to provide a master device and a communication control method capable of satisfactorily managing slave units in a system including a plurality of slave units. That is.

(1) In order to solve the above problems, the master device according to a certain aspect of the present invention is a master device that communicates with a power information acquisition device via a power line, and requests a communication connection with the master device itself. A counting unit that counts the required number of the power information acquisition devices that are connected and the number of connections that is the number of the power information acquisition devices that have established the communication connection, and the communication connection can be established. When the parent device of its own is operating in a state where the number of connectable units, which is the number of power information acquisition devices, is limited to a predetermined value, the sum of the requested number and the connected number counted by the counting unit is When the value exceeds the predetermined value, a processing unit that performs relaxation processing for increasing the number of connectable units is provided.

(5) In order to solve the above problems, the communication control method according to a certain aspect of the present invention is a communication control method in a master device that communicates with a power information acquisition device via a power line, and is a communication control method in the master device of its own. The step of counting the requested number of the power information acquisition devices requesting the communication connection and the number of connections which is the number of the power information acquisition devices having established the communication connection, and the communication connection. When the parent device of its own is operating in a state where the number of connectable units, which is the number of power information acquisition devices that can be established, is limited to a predetermined value, the sum of the counted requested number and the connected number is said. When the value exceeds a predetermined value, a step of performing a relaxation process for increasing the number of connectable units is included.

The present invention can be realized not only as a parent device provided with such a characteristic processing unit, but also as a program for causing a computer to execute such a characteristic processing step, or an electric power provided with the parent device. It can be realized as an information collection system. Further, the present invention can be realized as a semiconductor integrated circuit that realizes a part or all of the parent device.

According to the present invention, in a system including a plurality of slave units, the slave units can be managed satisfactorily.

FIG. 1 is a diagram showing a configuration of a power information collection system according to an embodiment of the present invention. FIG. 2 is a diagram showing an example of each device and wiring state in the power information collection system according to the embodiment of the present invention. FIG. 3 is a diagram showing an example of a network topology in the power information collection system according to the embodiment of the present invention. FIG. 4 is a diagram showing an example of a MAC frame used in the power information acquisition device according to the embodiment of the present invention. FIG. 5 is a diagram showing an example of a sequence when a slave device in the power information collection system according to the embodiment of the present invention performs an entry process. FIG. 6 is a diagram showing a comparative example of a sequence when the parent device stops operating. FIG. 7 is a diagram showing an example of a transmission period of each information in the power information collection system according to the embodiment of the present invention. FIG. 8 is a diagram showing an example of a sequence when the parent device in the power information collection system according to the embodiment of the present invention is replaced. FIG. 9 is a diagram showing a configuration of a master device in the power information collection system according to the embodiment of the present invention. FIG. 10 is a diagram showing an example of a list of child devices held by the parent device in the power information collection system according to the embodiment of the present invention. FIG. 11 is a diagram showing an example of a sequence when the parent device in the power information collecting system according to the embodiment of the present invention performs mitigation determination processing. FIG. 12 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention receives a connection request. FIG. 13 is a diagram showing an example of a connection request list held by the storage unit in the parent device according to the embodiment of the present invention. FIG. 14 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention processes a connection request. FIG. 15 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention performs relaxation processing. FIG. 16 is a diagram showing an example of a transmission period of each information in the power information collection system according to the embodiment of the present invention. FIG. 17 is a diagram showing an example of a sequence when the parent device in the power information collection system according to the embodiment of the present invention transmits a timing change request to the child device. FIG. 18 is a flowchart defining an operation procedure when a modified example of the parent device according to the embodiment of the present invention performs relaxation processing. FIG. 19 is a diagram showing an example of allocation of a power information transmission period to each child device in the power information collection system according to the embodiment of the present invention. FIG. 20 is a diagram showing an example of a sequence when a child device in the power information collection system according to the embodiment of the present invention is separated from the parent device.

First, the contents of the embodiments of the present invention will be listed and described.

(1) The master device according to the embodiment of the present invention is a master device that communicates with a power information acquisition device via a power line, and the power information acquisition requesting a communication connection with the master device itself. A counting unit that counts the required number of devices, the number of connected power information acquisition devices that have established the communication connection, and the number of power information acquisition devices that can establish the communication connection. When the sum of the requested number of units and the number of connected units counted by the counting unit exceeds the predetermined value when the parent device of the user is operating in a state where a certain connectable number of units is limited to a predetermined value. It is provided with a processing unit that performs relaxation processing for increasing the number of connectable units.

With such a configuration, for example, the number of power information acquisition devices that try to come under the control of the own parent device due to the failure of another parent device increases, and the sum of the requested number and the number of connected devices exceeds a predetermined value. Even in such a case, the number of connectable units can be increased. As a result, it is possible to establish a communication connection with the power information acquisition device that is going to be under the control of its own parent device, so that the power information transmission destination is lost because the parent device is not under control. It is possible to prevent the device from being generated. Therefore, in a system including a plurality of slave units, the slave units can be managed satisfactorily. As a result, it is possible to prevent the power information from the power information acquisition device that is not under the control of the parent device from being lost.

(2) Preferably, the processing unit further performs a process for disconnecting the communication connection with the power information acquisition device for which the communication connection is newly established by the relaxation process.

With such a configuration, for example, when a new parent device is provided in place of another failed parent device, the power information acquisition device that newly establishes a communication connection with its own parent device by mitigation processing , It is possible to establish a communication connection with the new parent device capable of performing better communication.

(3) Preferably, the parent device and each of the power information acquisition devices having established the communication connection transmit and receive information in a periodically repeated information period, and the power information acquisition device performs power information during the information period. The processing unit performs a process of extending the power information transmission period as the relaxation process, including a power information transmission period for transmitting the power information.

For example, when the length of the power information transmission period is set according to the number of connectable units before the relaxation process is performed, the power information from the number of power information acquisition devices exceeding a predetermined value is transmitted in the power information transmission period. It can be difficult to do. With the above configuration, power information from a number of power information acquisition devices exceeding a predetermined value can be transmitted during the power information transmission period.

(4) Preferably, the parent device and each of the power information acquisition devices having established the communication connection transmit and receive information in a periodically repeated information period, and the power information acquisition device performs power information during the information period. The processing unit includes, as the relaxation process, each of the electric powers exceeding the predetermined value in the electric power information transmission period of one of the two consecutive electric power information transmission periods. A part of the information acquisition device is made to transmit the electric power information, and the remaining electric power information acquisition device that exceeds the predetermined value in the other electric power information transmission period is made to transmit the electric power information.

For example, when the length of the power information transmission period is set according to the number of connectable units before the relaxation process is performed, the power information from the number of power information acquisition devices exceeding a predetermined value is transmitted in the power information transmission period. It can be difficult to do. With the above configuration, the number of power information acquisition devices exceeding a predetermined value can obtain an opportunity to transmit power information in one of two consecutive power information transmission periods, so that the power information transmission destination can be obtained. Can be prevented from being left in a lost state.

(5) The communication control method according to the embodiment of the present invention is a communication control method in a master device that communicates with a power information acquisition device via a power line, and requests a communication connection with the master device itself. A step of counting the required number of power information acquisition devices, the number of connected power information acquisition devices that have established the communication connection, and the power information acquisition that can establish the communication connection. When the number of connectable units, which is the number of devices, is limited to a predetermined value and the sum of the counted requested number and the connected number exceeds the predetermined value, the connectable number is increased. Includes steps to perform processing for.

With such a configuration, for example, the number of power information acquisition devices that try to come under the control of the own parent device due to the failure of another parent device increases, and the sum of the requested number and the number of connected devices exceeds a predetermined value. Even in such a case, the number of connectable units can be increased. As a result, it is possible to establish a communication connection with the power information acquisition device that is going to be under the control of its own parent device, so that the power information transmission destination is lost because the parent device is not under control. It is possible to prevent the device from being generated. Therefore, in a system including a plurality of slave units, the slave units can be managed satisfactorily. As a result, it is possible to prevent the power information from the power information acquisition device that is not under the control of the parent device from being lost.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. The same or corresponding parts in the drawings are designated by the same reference numerals, and the description thereof will not be repeated. In addition, at least a part of the embodiments described below may be arbitrarily combined.

[Configuration and basic operation]
FIG. 1 is a diagram showing a configuration of a power information collection system according to an embodiment of the present invention.

With reference to FIG. 1, the power information collection system 301 includes a plurality of smart meters 101, a plurality of concentrators 102, and a server 103. The server 103 is, for example, a headend. The smart meter 101 is an example of a power information acquisition device. The concentrator 102 is an example of a parent device.

The power information collection system 301 is not limited to the configuration including one server 103, and may be configured to include a plurality of servers 103.

The electric power information collection system 301 is used, for example, in an apartment house 151. Each smart meter 101 is connected to the concentrator 102 via a power line 161. Specifically, for example, a plurality of power lines 161 are arranged in the vertical direction of the upper and lower floors in an apartment house 151, and a smart meter 101 is connected to each floor.

The concentrator 102 communicates with the smart meter 101 via the power line 161. More specifically, the smart meter 101 and the concentrator 102 exchange various information by, for example, power line communication using the power line 161.

The smart meter 101 is a slave unit in power line communication, and the concentrator 102 is a master unit in the power line communication. Hereinafter, the smart meter 101 and the concentrator 102 will also be referred to as a child device 101 and a parent device 102, respectively.

The slave device 101 is a power measuring instrument having a communication function. The child device 101 periodically acquires power information indicating the power consumed in the home or business establishment to be measured, for example, every 30 minutes, and transmits the acquired power information to the parent device 102.

Further, the child device 101 can communicate with the parent device 102 via another child device 101. That is, the child device 101 has a function of relaying communication between the other child device 101 and the parent device 102.

Specifically, the child device 101 may directly transmit the acquired power information to the parent device 102 without going through another child device 101, and the child device 101 may transmit the acquired power information to one or more other children. It may be transmitted to the parent device 102 via the device 101.

The parent device 102 and the server 103 exchange various information via the Internet 10 by wire communication or wireless communication.

The parent device 102 receives power information from each child device 101. The parent device 102 receives power information from each child device 101, aggregates the received power information and transmits it to the server 103, or individually transmits the received power information to the server 103. The power information includes, for example, the ID of the child device 101.

The server 103 transmits, for example, power charge information and firmware update information to the parent device 102. When the parent device 102 receives the power charge information and the update information from the server 103, the parent device 102 transmits the received power charge information and the update information to the child device 101.

When the child device 101 receives the power charge information from the parent device 102, the child device 101 transmits the received power charge information to another device such as HEMS (Home Energy Management System) (not shown).

When the child device 101 receives the update information from the parent device 102, the child device 101 updates its own firmware using the received update information.

Communication between the parent device 102 and the child device 101, and communication between each child device 101 are described, for example, in Non-Patent Document 1 (G3-PLC Alliance, "Narrowband OFDM PLC specializations for G3-PLC networks", G3-PLC Alrance, 2014. It is carried out according to the G3-PLC standard described in (October, 2014).

Further, for example, the information transmitted / received between the child device 101, the parent device 102, and the server 103 is encrypted and decrypted according to a predetermined method.

FIG. 2 is a diagram showing an example of each device and wiring state in the power information collection system according to the embodiment of the present invention. FIG. 2 typically shows two power lines 161A and 161B in the housing complex 151.

With reference to FIG. 2, three-phase AC power of, for example, 6.6 kV is supplied from the power system 171 to the housing complex 151. The AC power from the power system 171 is converted into 200 V single-phase three-wire AC power by, for example, transformers 104A and 104B and supplied to each floor.

A transformer 104A and a parent device 102A, which is a parent device 102, are connected to the power line 161A.

A transformer 104B and a parent device 102B, which is a parent device 102, are connected to the power line 161B.

The number of child devices 101 that can be managed by the parent device 102 is limited to, for example, 100. Therefore, when the power information collection system 301 is installed in the housing complex 151, 100 or less child devices 101 are connected to the power line 161A.

In this example, 60 slave devices 101A, which are slave devices 101, are connected to the power line 161A. Similarly, 60 slave devices 101B, which are slave devices 101, are connected to the power line 161B.

In addition, 59 or less or 61 or more and 100 or less child devices 101A may be connected to the power line 161A. Further, 59 or less or 61 or more and 100 or less child devices 101B may be connected to the power line 161B. Further, the power information collecting system 301 is not limited to the configuration including the parent devices 102A and 102B, and may be configured to include three or more parent devices 102.

Hereinafter, each of the transformers 104A and 104B will also be referred to as a transformer 104. Each of the power lines 161A and 161B is also referred to as a power line 161.

The child device 101 has a MAC (Media Access Control) address as an example of a device-specific identifier. The MAC address is set, for example, when the device is manufactured. The ID is, for example, this MAC address.

Specifically, each of the 60 slave devices 101A has a MAC address of MAC-A001 to MAC-A060. Each of the 60 slave devices 101B has a MAC address of MAC-B001 to MAC-B060.

[Network Topology]
FIG. 3 is a diagram showing an example of a network topology in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 3, the parent device 102 and the child device 101 have, for example, a PAN_ID (Personal Area Network Identification) and a short address.

Each parent device 102 has a different PAN_ID. Further, the short address of each parent device 102 is set to, for example, zero.

The parent device 102 manages one or a plurality of child devices 101, and exchanges authentication information, power information, and the like with the managed child device 101.

The child device 101 establishes a communication connection with the parent device 102 that is the transmission destination of the power information. Specifically, the child device 101A having the MAC address of MAC-A001 (hereinafter, also referred to as the child device 101A-1) establishes a communication connection with, for example, the parent device 102A when it is not under the control of the parent device 102. ..

In this case, the child device 101A-1 directly exchanges authentication information, power information, and the like with the parent device 102A.

Further, when the child device 101A having the MAC address of MAC-A002 and MAC-A003 (hereinafter, also referred to as child devices 101A-2 and 101A-3, respectively) is not under the control of the parent device 102, the child device 101A- A communication connection is established with the parent device 102A via 1.

In this case, the child devices 101A-2 and 101A-3 exchange authentication information, power information, and the like with the parent device 102A via the child device 101A-1.

That is, the child device 101A-1 serves as a hop destination for relaying information exchanged between the parent device 102A and the child devices 101A-2 and 101A-3. The child devices 101A-2 and 101A-3 may establish a communication connection with the parent device 102A without going through the child device 101A-1.

The PAN_ID of the parent device 102A and the child devices 101A-1, 101A-2, 101A-3 under the control of the parent device 102A is, for example, "0001".

Similarly, the PAN_ID of the child device 101A having the MAC addresses of MAC-A004 to MAC-A060 (not shown) is "0001".

Further, each device having the same PAN_ID is given a short address which is a different identifier. Specifically, the short addresses of the child devices 101A-1, 101A-2, and 101A-3 are non-zero values and do not overlap with each other, for example, "1", "2", and "3", respectively. ..

The child device 101A having the MAC addresses of MAC-A004 to MAC-A060 (not shown) establishes a communication connection with the parent device 102A in the same manner as the child devices 101A-1 to 101A-3.

Further, the short addresses of the child devices 101A having the MAC addresses of MAC-A004 to MAC-A060 are, for example, "4" to "60", respectively.

The short address of the child device 101A having the MAC address of MAC-A001 to MAC-A060 is given by, for example, the parent device 102A.

The parent device 102A and the child device 101A having the MAC addresses of MAC-A001 to MAC-A060 form a PA (Personal Area) network NWA.

Similarly, the parent device 102B manages the child device 101B having the MAC address of MAC-B001 to MAC-B060. The PAN_ID of the parent device 102B and each child device 101B under the control of the parent device 102B is, for example, "0002".

The short address of the child device 101B having the MAC address of MAC-B001 to MAC-B060 is a value other than zero and does not overlap with each other, for example, "1" to "60", respectively. These short addresses are assigned by, for example, the parent device 102B.

The parent device 102B and the child device 101B having the MAC addresses of MAC-B001 to MAC-B060 form a PA network NWB.

That is, it is possible to determine which PA network the parent device 102 and the child device 101 are connected to by communication based on the PAN_ID.

[MAC frame]
FIG. 4 is a diagram showing an example of a MAC frame used in the power information acquisition device according to the embodiment of the present invention. FIG. 4 shows a format of a MAC frame according to the G3-PLC standard described in Non-Patent Document 1.

With reference to FIG. 4, the MAC frame 71 includes a MAC header, a MAC payload, and a MAC footer.

The MAC header may be, for example, "Segment control", "Frame control", "Sequence number", "Destination PAN", "Destination address". , "Source PAN", "Source address" and "Auxiliary security header". The lengths of these fields are 3 octets, 2 octets, 1 octet, 2 octets, 2 octets, 2 octets, 2 octets, and 2 octets, respectively.

In the "destination address" field, for example, the short address of the destination of the MAC frame 71 is stored. Further, in the "source address" field, for example, the short address of the source of the MAC frame 71 is stored.

The MAC frame 71 may not include at least one of the "destination PAN", "destination address", "source PAN", "source address", and "secondary security header" fields.

Further, in the "destination address" field, for example, the long address of the destination of the MAC frame 71 may be stored. Further, the long address of the source of the MAC frame 71 may be stored in the "source address" field.

Here, the destination long address and the source long address are, for example, addresses based on the destination MAC address and the source MAC address, respectively.

[Operation flow]
Each device in the power information collection system 301 includes a computer, and an arithmetic processing unit such as a CPU in the computer reads a program including a part or all of each step of the following sequence diagram or flowchart from a memory (not shown). Run. The programs of these plurality of devices can be installed from the outside. The programs of these plurality of devices are distributed in a state of being stored in a recording medium.

FIG. 5 is a diagram showing an example of a sequence when a slave device in the power information collection system according to the embodiment of the present invention performs an entry process.

With reference to FIG. 5, when the parent devices 102A and 102B have already constructed the PA network, for example, it is assumed that the power of the child device 101A-1 is turned on and the child device 101A-1 starts operating. ..

First, the child device 101A-1 broadcasts a beacon request in order to search for the parent device 102 (step S102).

Next, when the parent device 102B receives the beacon request from the child device 101A-1, the parent device 102B creates a beacon BB as a response to the received beacon request, and transmits the created beacon BB to the child device 101A-1 (step S104). ..

In the beacon BB, the PAN_ID or “0002” of the parent device 102B and the short address or zero of the parent device 102B are stored in the “source PAN” field and the “source address” field in the MAC frame 71, respectively.

Next, when the parent device 102A receives the beacon request from the child device 101A-1, it creates a beacon BA as a response to the received beacon request and transmits the created beacon BA to the child device 101A-1 (step S106). ..

In the beacon BA, the PAN_ID of the parent device 102A, that is, "0001" and the short address of the parent device 102A, that is, zero, are stored in the "source PAN" field and the "source address" field in the MAC frame 71, respectively.

Next, when the child device 101A-1 receives the beacon from the parent devices 102A and 102B, the child device 101A-1 performs a selection process of selecting the parent device 102 to be the communication destination based on each received beacon (step S108). ..

Specifically, the child device 101A-1 selects, for example, the parent device 102 having the best communication quality with itself, in this example, the parent device 102A, as the parent device 102 to be communicated with by itself.

Next, the child device 101A-1 performs an entry process for starting communication with the parent device 102A, which is the transmission destination of the power information (step S110).

More specifically, the child device 101A-1 transmits, for example, a connection request including its own long address and the PAN_ID of the parent device 102A, specifically Joining, to the parent device 102A.

When the parent device 102A receives the connection request from the child device 101A-1, the parent device 102A performs a content confirmation process of the received connection request. When the parent device 102A confirms that the PAN_ID included in the connection request matches its own PAN_ID, the parent device 102A determines that it manages the child device 101A-1.

Then, authentication information is exchanged between the child device 101A-1 and the parent device 102A using the long address included in the connection request, and the parent device 102A authenticates the child device 101A-1.

As a result, a direct communication connection is established between the child device 101A-1 and the parent device 102A.

Next, the slave device 101A-1 measures the power consumed in the measurement target (step S114).

Next, the child device 101A-1 transmits power information indicating the measurement result to the parent device 102A (step S116).

Next, the child device 101A-1 transmits a connection confirmation request to the parent device 102A in order to confirm communication with the parent device 102A (step S118).

Next, when the parent device 102A receives the connection confirmation request from the child device 101A-1, it transmits an ACK indicating that the connection confirmation request has been received to the child device 101A-1 (step S120).

Next, when the child device 101A-1 receives the ACK from the parent device 102A, it confirms that the communication with the parent device 102A is secured by receiving the ACK (step S122).

Here, the operations of steps S114 to S122 are repeated, for example, every 30 minutes.

The order of steps S104 and S106 is not limited to the above, and the order may be changed.

Further, in the power information collection system 301, in steps S118 to S122, the child device 101A-1 transmits a connection confirmation request to the parent device 102A, and the parent device 102A transmits ACK to the child device 101A-1. The child device 101A-1 is configured to confirm communication with the parent device 102A, but the present invention is not limited to this. For example, the child device 101A-1 transmits power information to the parent device 102A, and the parent device 102A transmits ACK to the child device 101A-1 in response to receiving the power information, so that the child device 101A-1 becomes the parent device 101A-1. The configuration may be such that communication with the device 102A is confirmed.

Further, the child device 101A having the MAC address of MAC-A002 to MAC-A060 establishes a communication connection with the parent device 102A by performing the same operation as the child device 101A-1.

Further, the child device 101B having the MAC address of MAC-B001 to MAC-B060 also establishes a communication connection with the parent device 102B in the same manner.

FIG. 6 is a diagram showing a comparative example of a sequence when the parent device stops operating.

With reference to FIG. 6, it is assumed that the parent devices 102A and 102B have already constructed the PA network and the transmission destination of the power information of the child device 101A-1 is set to the parent device 102A.

First, the parent device 102A fails, for example, and stops its operation (step S202).

Next, the slave device 101A-1 measures the power consumed in the measurement target (step S204).

Next, the child device 101A-1 transmits the power information indicating the measurement result to the parent device 102A (step S206).

However, here, since the parent device 102A has stopped operating, the power information is not received by the parent device 102A.

Next, the child device 101A-1 transmits a connection confirmation request to the parent device 102A (step S208).

However, here, since the parent device 102A has stopped operating, the child device 101A-1 cannot receive the ACK from the parent device 102A.

Next, since the child device 101A-1 cannot receive the ACK from the parent device 102A within the predetermined timeout time, for example, it is confirmed that a communication error has occurred in the communication with the parent device 102A (step S210). ..

The operations of steps S204 to S210 are repeated N1 a predetermined number of times, for example.

Next, when the child device 101A-1 confirms, for example, the occurrence of a communication error with the parent device 102A N1 times in a row, the child device 101A-1 decides to leave the parent device 102A and search for a new parent device 102 (step). S212).

Next, the child device 101A-1 broadcasts a beacon request in order to search for a new parent device 102 (step S214).

However, here, the parent device 102A does not receive the beacon request because the operation is stopped.

Next, when the parent device 102B receives the beacon request from the child device 101A-1, the parent device 102B creates a beacon BB as a response to the received beacon request and transmits the created beacon BB to the child device 101A-1 (step S216). ..

Next, when the child device 101A-1 receives the beacon BB from the parent device 102B, the child device 101A-1 performs a selection process based on the received beacon BB (step S218).

Here, the child device 101A-1 selects the parent device 102B as the parent device 102 with which it should communicate.

Next, the child device 101A-1 performs an entry process for starting communication with the parent device 102B, which is the transmission destination of the power information (step S220).

As a result, a direct communication connection is established between the child device 101A-1 and the parent device 102B.

In step S202, the stoppage of the operation of the master device 102A occurred due to a failure, but the present invention is not limited to this. For example, the stoppage of the operation of the master device 102A is replacement, maintenance, and repair of the parent device 102A. It may also occur when the power is turned off.

[Issue 1]
FIG. 7 is a diagram showing an example of a transmission period of each information in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 7, the parent device 102 and each child device 101 that has established a communication connection with the parent device 102 transmit and receive information, for example, in a periodically repeated information period. This information period includes, for example, a power information transmission period Pp for the child device 101 to transmit power information.

In the electric power information collection system 301, for example, an information period having a length of 30 minutes is set as a unit for transmitting various types of information. The information period is set to be continuous in time, for example.

In this example, from zero to 60 minutes per hour, a first information period starting from zero minutes and a second information period starting from 30 minutes are provided.

Each of the first information period and the second information period includes a power information transmission period Pp, a time synchronization period P1, a power charge transmission period P2, and a firmware update period P3 in order from the beginning.

The power information transmission period Pp, the time synchronization period P1, the power charge transmission period P2, and the firmware update period P3 provide power information, synchronization information for time-synchronizing the child device 101 and the parent device 102, power charge information, and update information. It is a period for each transmission.

In this example, the power information transmission period Pp is provided at the beginning of the information period. The power information transmission period Pp may be provided after the second information period. Further, the order of the power information transmission period Pp in the information period may be different for each information period.

Further, the information period is not limited to the configuration including the time synchronization period P1, the power charge transmission period P2, and the firmware update period P3, and may be a configuration including a part of these, or a configuration including other periods. There may be.

The length of the power information transmission period Pp is fixed to, for example, 5 minutes in order to smoothly transmit synchronization information, power charge information, update information, and the like other than power information in the PA network.

Since the length of the power information transmission period Pp is fixed, the number of connectable devices, which is the number of child devices 101 to which the parent device 102 can establish a communication connection, is limited to a predetermined value.

More specifically, in order to complete the transmission of power information in the PA network within the power information transmission period Pp, for example, 100 units are set as the upper limit of the number of child devices 101 that can be managed by the parent device 102. Will be done.

Further, in the operation flow shown in FIG. 6, in step S220, the child device 101A-1 establishes a communication connection with the parent device 102B.

In this state, since the parent device 102B has already established a communication connection with the 60 child devices 101B and the child device 101A-1, the number of the child devices 101 for which the parent device 102B has established a communication connection. The number of connected units will be 61.

Further, when the child device 101A having the MAC address of MAC-A002 to MAC-A060 transmits a connection request to the parent device 102B in the same manner as the child device 101A-1, it requests a communication connection with the parent device 102B. The required number of slave devices 101 is 59.

In such a state, the sum of the number of connected devices and the number of requested devices exceeds 100, which is the number of connectable devices. Therefore, 20 of the slave devices 101A having the MAC addresses of MAC-A002 to MAC-A060 are used. The communication connection with the parent device 102B cannot be established.

In the power information collection system 301, these 20 slave devices 101A lose the transmission destination of the power information, so that the power information is lost.

FIG. 8 is a diagram showing an example of a sequence when the parent device in the power information collection system according to the embodiment of the present invention is replaced.

With reference to FIG. 8, it is assumed that the parent device 102B has already constructed a PA network and the transmission destination of the power information of the child device 101A-1 is set to the parent device 102B.

First, the slave device 101A-1 measures the power consumed in the measurement target (step S252).

Next, the child device 101A-1 transmits the power information indicating the measurement result to the parent device 102B (step S254).

Next, the child device 101A-1 transmits a connection confirmation request to the parent device 102B (step S256).

Next, when the parent device 102B receives the connection confirmation request from the child device 101A-1, it transmits an ACK indicating that the connection confirmation request has been received to the child device 101A-1 (step S258).

Next, when the child device 101A-1 receives the ACK from the parent device 102B, it confirms that the communication with the parent device 102B is secured by the reception of the ACK (step S260).

Here, the operations of steps S252 to S260 are repeated, for example, every 30 minutes.

Next, the parent device 102C is connected to the power line 161A instead of the failed parent device 102A (step S262). The PAN_ID of the parent device 102C is set to, for example, "0003".

Next, the slave device 101A-1 measures the power consumed in the measurement target (step S264).

Next, the child device 101A-1 transmits the power information indicating the measurement result to the parent device 102B (step S266).

Next, the child device 101A-1 transmits a connection confirmation request to the parent device 102B (step S268).

Next, when the parent device 102B receives the connection confirmation request from the child device 101A-1, it transmits an ACK indicating that the connection confirmation request has been received to the child device 101A-1 (step S270).

Next, when the child device 101A-1 receives the ACK from the parent device 102B, it confirms that the communication with the parent device 102B is secured by the reception of the ACK (step S272).

Here, the operations of steps S264 to S272 are repeated, for example, every 30 minutes.

[Issue 2]
In the above-mentioned operation flow, the child device 101A-1 sets the parent device 102B as the transmission destination of the power information. In this case, as shown in FIG. 2, the child device 101A-1 communicates with the parent device 102B via the transformers 104A and 104B.

In such communication via the transformer 104, the signal level is greatly attenuated, so that the communication success rate may decrease.

Therefore, it is preferable that the child device 101 has a configuration in which the parent device 102 capable of communicating without going through the transformer 104 is the transmission destination of the power information. Specifically, the child device 101A-1 preferably has a configuration in which the parent device 102C capable of communicating without going through the transformers 104A and 104B is used as the transmission destination of power information.

Further, in step S262, the parent device 102C is connected to the power line 161A instead of the failed parent device 102A. However, the child device 101A-1 transmits the power information to the parent device 102B even after the parent device 102C is connected to the power line 161A (step S266).

That is, even if the parent device 102C capable of transmitting power information with a good success rate is connected to the power line 161A, the success rate of power information transmission in the child device 101A-1 remains low.

Further, among the child devices 101A having the MAC addresses of MAC-A002 to MAC-A060, the child device 101A that has established a communication connection with the parent device 102B also has a success rate of power information transmission as in the child device 101A-1. It stays down.

Therefore, in the power information collection system according to the embodiment of the present invention, such a problem is solved by the following configuration and operation.

[Configuration and operation of parent device 102]
FIG. 9 is a diagram showing a configuration of a master device in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 9, the parent device 102 includes a communication unit 21, a counting unit 22, a storage unit 24, and a processing unit 25.

Hereinafter, the processing performed by the parent device 102B will be described, but the same processing will be performed by the parent device 102A.

The communication unit 21 in the parent device 102B communicates with the child device 101 via the power line 161 in accordance with the G3-PLC standard described in Non-Patent Document 1.

More specifically, the communication unit 21 can communicate with the child device 101B via the power line 161B, and can communicate with the child device 101A via the power line 161B, the transformer 104B, the power system 1711, the transformer 104A, and the power line 161A. be.

When the processing unit 25 receives a beacon request from the child device 101 via the communication unit 21, it creates a beacon as a response to the received beacon request and transmits the created beacon to the child device 101A via the communication unit 21.

FIG. 10 is a diagram showing an example of a list of child devices held by the parent device in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 10, the storage unit 24 is a non-volatile memory such as a flash memory, and holds identifier information including an identifier of a child device 101 to which its own parent device 102 has established a communication connection.

Specifically, the storage unit 24 holds, for example, a child device list Lst1 including the MAC address of each child device 101B to which its parent device 102B has established a communication connection.

In this example, the child device list Lst1 includes the MAC addresses of 60 child devices 101B connected to its own parent device 102B without going through the transformer 104, that is, MAC-B001 to MAC-B060.

FIG. 11 is a diagram showing an example of a sequence when the parent device in the power information collecting system according to the embodiment of the present invention performs mitigation determination processing.

With reference to FIG. 11, it is assumed that the parent devices 102A and 102B have already constructed the PA network and the transmission destination of the power information of the child device 101A-1 is set to the parent device 102A.

The operation of steps S302 to S318 is the same as the operation of steps S202 to S218 shown in FIG.

Next, the child device 101A-1 transmits a connection request including its own long address and the PAN_ID of the parent device 102B, specifically, Joining to the parent device 102B (step S320).

Next, when the parent device 102B receives the joining from the child device 101A-1, the parent device 102B performs a mitigation determination process based on the received joining (step S322).

[Mitigation judgment processing]
FIG. 12 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention receives a connection request.

FIG. 13 is a diagram showing an example of a connection request list held by the storage unit in the parent device according to the embodiment of the present invention.

With reference to FIGS. 12 and 13, the processing unit 25 processes the connection request received from the child device 101 by the communication unit 21.

More specifically, the processing unit 25 buffers the MAC address included in the connection request received from the child device 101 by the communication unit 21 in the storage unit 24.

First, the processing unit 25 in the parent device 102B waits for the MAC address buffering until the joining is received from the child device 101 via the communication unit 21 (NO in step S402).

Then, when the processing unit 25 receives the joining from the child device 101 via the communication unit 21 (YES in step S402), the processing unit 25 acquires the long address and the PAN_ID from the received joining (step S404).

Next, the processing unit 25 confirms whether or not the acquired PAN_ID and the PAN_ID of its own parent device 102B match (step S406).

When the acquired PAN_ID and the PAN_ID of its own parent device 102B match (YES in step S406), the processing unit 25 generates a MAC address based on the acquired long address and displays it in the connection request list Lst2 in the storage unit 24. Register (step S408).

Next, when the acquired PAN_ID and the PAN_ID of its own parent device 102B do not match (NO in step S406), or when the MAC address is registered in the connection request list Lst2 (step S408), the processing unit 25 performs the communication unit 21. It waits for MAC address buffering (NO in step S402) until a new joining is received from the child device 101 via the device.

According to the above operation flow, the MAC addresses of the 60 child devices 101A connected to the parent device 102B via the transformer 104, that is, MAC-A001 to MAC-A060, are registered in the connection request list Lst2.

FIG. 14 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention processes a connection request.

With reference to FIG. 14, the processing unit 25 sequentially processes the buffered MAC addresses.

First, the processing unit 25 in the parent device 102B confirms whether or not the MAC address is registered in the connection request list Lst2 (see FIG. 13) (step S502).

If the MAC address is not registered in the connection request list Lst2, the processing unit 25 waits for the processing of the MAC address (NO in step S502).

On the other hand, when the MAC address is registered in the connection request list Lst2 (YES in step S502), the processing unit 25 acquires one MAC address from the connection request list Lst2 (step S504).

Next, the processing unit 25 establishes a communication connection with the child device 101 having the acquired MAC address (step S506).

More specifically, the processing unit 25 generates, for example, a long address based on the acquired MAC address, and uses the generated long address to exchange authentication information with the child device 101 via the communication unit 21. This establishes a communication connection with the child device 101.

Next, the processing unit 25 deletes the acquired MAC address from the connection request list Lst2 (step S508).

Next, the processing unit 25 registers the acquired MAC address in the child device list Lst1 (step S510).

Next, the processing unit 25 confirms whether or not the MAC address is registered in the connection request list Lst2 (step S502).

The order of steps S506 to S510 is not limited to the above, and a part or all of the order may be changed.

With reference to FIG. 9 again, the counting unit 22 counts the requested number of units and the number of connected units.

More specifically, the counting unit 22 refers to the child device list Lst1 (see FIG. 10) and the connection request list Lst2 (see FIG. 13) in the storage unit 24, and connects with the number of MAC addresses included in the child device list Lst1. The sum with the number of MAC addresses included in the request list Lst2 is calculated, and the calculation result is output to the processing unit 25.

When the parent device 102B of the processing unit 25 is operating in a state where the number of connectable units is limited to, for example, 100, the sum of the requested number and the number of connected units counted by the counting unit 22 exceeds 100. At that time, mitigation processing is performed to increase the number of connectable units.

More specifically, the processing unit 25 performs, for example, a process of extending the power information transmission period Pp as a mitigation process.

FIG. 15 is a flowchart defining an operation procedure when the parent device according to the embodiment of the present invention performs relaxation processing.

With reference to FIG. 15, the parent device 102B waits for a process of calculating the sum of the requested number of units and the number of connected units until, for example, the count timing for each predetermined cycle arrives (NO in step S602).

Then, when the count timing arrives (YES in step S602), the parent device 102B calculates the sum of the requested number of units and the number of connected units (step S604).

Next, when the calculated sum is equal to or less than a predetermined value, here, the upper limit value (NO in step S606), the parent device 102B calculates the sum of the requested number of units and the number of connected units until a new count timing arrives. (NO in step S602).

On the other hand, when the calculated sum is larger than the upper limit value (YES in step S606), the parent device 102B raises the upper limit value (step S608).

More specifically, when the processing unit 25 receives the calculation result from the counting unit 22, the processing unit 25 compares the received calculation result with the upper limit value, and if the calculation result is larger than the upper limit value, sets the upper limit value from 100 units to, for example, 150 units. Set to.

The 150 units are determined based on, for example, resources such as the memory capacity of the parent device 102B, communication frequency of various information, and the like.

Next, the parent device 102B extends the power information transmission period Pp (step S610).

FIG. 16 is a diagram showing an example of a transmission period of each information in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 16, the processing unit 25 in the parent device 102B changes each period as follows while maintaining the length of the first information period and the second information period shown in FIG. 7 at 30 minutes. do.

That is, for example, the processing unit 25 extends the length of the power information transmission period Pp from 5 minutes to 6 minutes, and increases the total length of the time synchronization period P1, the power charge transmission period P2, and the firmware update period P3 from 25 minutes. Reduce to 24 minutes.

With reference to FIG. 15 again, the parent device 102B creates a timing change request indicating the start timing and the end timing of the newly set power information transmission period Pp, and transmits the created timing change request to the child device 101 ( Step S612).

Specifically, the processing unit 25 transmits joining to the child device 101 (hereinafter, also referred to as a connected child device) to which the parent device 102B of the parent device 102B has established a communication connection, and the child device 102B of the parent device 102B. A timing change request is transmitted to the device 101 (hereinafter, also referred to as a connection requester device) via the communication unit 21.

More specifically, the processing unit 25 sends a timing change request to the child device 101 having the MAC address included in the child device list Lst1 and the child device 101 having the MAC address included in the connection request list Lst2 via the communication unit 21. Send.

The order of steps S608 to S612 is not limited to the above, and a part or all of the order may be changed.

FIG. 17 is a diagram showing an example of a sequence when the parent device in the power information collection system according to the embodiment of the present invention transmits a timing change request to the child device.

With reference to FIG. 17, first, the parent device 102B transmits a timing change request to the connected child device (step S702).

Next, when the connected child device receives the timing change request from the parent device 102B, the connected child device performs a change process for changing each period including the power information transmission period Pp according to the received timing change request (step S704).

Next, the connected child device transmits a timing change response indicating that the change process is completed to the parent device 102B (step S706).

When the processing unit 25 in the parent device 102B receives the timing change response from the connected child device via the communication unit 21, it recognizes that the timing change in the connected child device has been completed normally.

Here, the operations of steps S702 to S706 are performed on all the connected child devices having the MAC addresses included in the child device list Lst1.

Next, the parent device 102B transmits a timing change request to the connection requester device (step S708).

Next, when the connection requester device receives the timing change request from the parent device 102B, the connection requester device performs a change process for changing each period including the power information transmission period Pp according to the received timing change request (step S710).

Next, the connection requester device transmits a timing change response indicating that the change process is completed to the parent device 102B (step S712).

When the processing unit 25 in the parent device 102B receives the timing change response from the connection requester device via the communication unit 21, it recognizes that the timing change in the connection requester device has been completed normally.

Here, the operations of steps S708 to S712 are performed on all the connected child devices having the MAC addresses included in the connection request list Lst2.

In this way, by extending the power information transmission period Pp, it is possible to complete the transmission of the power information from the connected child device and the connection requester device to the parent device 102B within the power information transmission period Pp.

The order of steps S702 to S706 and steps S708 to S712 is not limited to the above, and the order may be changed.

[Modification example of parent device 102]
With reference to FIG. 9 again, the processing unit 25 is configured to perform a process of extending the power information transmission period Pp as a relaxation process, but the present invention is not limited to this. For example, as a relaxation process, the processing unit 25 causes a part of each child device 101 that exceeds a predetermined value in the power information transmission period of one of the two continuous power information transmission periods to transmit the power information, and the other power is transmitted. The power information is transmitted to the rest of each slave device 101 that exceeds a predetermined value during the information transmission period.

The slave device 101 transmits, for example, power information to be transmitted in two consecutive power information transmission periods in one power information transmission period.

FIG. 18 is a flowchart defining an operation procedure when a modified example of the parent device according to the embodiment of the present invention performs relaxation processing.

With reference to FIG. 18, the operation of steps S802 to S808 is the same as the operation of steps S602 to S608 shown in FIG.

Next, the parent device 102B performs an allocation process for allocating the power information transmission period Pp to the connected child device and the connection requesting child device (step S810).

FIG. 19 is a diagram showing an example of allocation of a power information transmission period to each child device in the power information collection system according to the embodiment of the present invention.

With reference to FIG. 19, when the processing unit 25 in the parent device 102B receives the calculation result from the counting unit 22, it compares the received calculation result with a predetermined value, that is, an upper limit value, and when the calculation result is larger than the upper limit value, Perform the following processing.

That is, the processing unit 25 sets the power information transmission period Pp in the first information period shown in FIG. 7 to the child device 101 having the MAC addresses of MAC-B001 to MAC-B060 and MAC-A001 to MAC-A040 (hereinafter, hereinafter. The first group child device (also referred to as a child device) allocates power information to a period during which it should be transmitted.

Further, the processing unit 25 refers to the power information transmission period Pp in the second information period shown in FIG. 7 as a child device 101 having a MAC address of MAC-A041 to MAC-A060 (hereinafter, also referred to as a second group child device). ) Assigns power information to the period during which it should be transmitted.

With reference to FIG. 18 again, the parent device 102B creates a timing change request indicating the start timing and the end timing of the newly set power information transmission period Pp, and transmits the created timing change request to the child device 101 ( Step S812).

More specifically, the processing unit 25 in the parent device 102B requests, for example, to transmit the power information for two times during the power information transmission period Pp (see FIG. 7) in the first information period. A timing change request addressed to the user is created, and the created timing change request is transmitted to the first group slave device via the communication unit 21.

Further, the processing unit 25 creates, for example, a timing change request addressed to the second group child device requesting that the power information for two times be transmitted during the power information transmission period Pp (see FIG. 7) in the second information period. Then, the created timing change request is transmitted to the second group slave device via the communication unit 21.

When the first group child device receives the timing change request from the parent device 102B, the first group child device transmits the power information for two times during the power information transmission period Pp (see FIG. 7) in the first information period according to the received timing change request. Perform the change process to set.

The first group child device transmits a timing change response indicating that the change process is completed to the parent device 102B.

When the second group child device receives the timing change request from the parent device 102B, the second group child device transmits the power information for two times during the power information transmission period Pp (see FIG. 7) in the second information period according to the received timing change request. Perform the change process to set.

The second group child device transmits a timing change response indicating that the change process is completed to the parent device 102B.

As shown in FIG. 4, since the MAC frame 71 includes a MAC header having a length of 16 octets and a MAC footer having a length of 4 octets, in a configuration in which power information for two times is transmitted at one time. It is possible to reduce the size of the information to be transmitted as compared with the configuration in which the power information for two times is transmitted in two times.

In the power information transmission period Pp in the first information period, the first group child device is made to transmit the power information for two times, and in the power information transmission period Pp in the second information period, the second group child device is made to transmit the power information for two times. With the configuration in which the power information is transmitted, the power information from these child devices 101 can be satisfactorily collected even when the number of child devices 101 exceeding the upper limit value before pulling up and the parent device 102B establish a communication connection.

[Leaving process]
With reference to FIG. 9 again, the processing unit 25 performs a process for disconnecting the communication connection with the child device 101 for which the communication connection is newly established by the relaxation process, for example.

FIG. 20 is a diagram showing an example of a sequence when a child device in the power information collection system according to the embodiment of the present invention is separated from the parent device.

First, for example, when the predetermined condition C1 is satisfied, the server 103 creates a withdrawal notification addressed to the child device 101A for disconnecting the communication connection from the child device 101A (step S902).

Here, the predetermined condition C1 is, for example, that the administrator of the server 103 has received an operation for disconnecting the communication connection from the slave device 101A.

The predetermined condition C1 is not limited to the above, and may be, for example, a state in which the child device 101A has established a communication connection with the parent device 102B via the transformer 104 for a predetermined time or longer.

Here, the predetermined time is calculated based on, for example, the time required for replacement of the parent device 102A.

In this case, the server 103 holds, for example, a list including the ID of each child device 101 to which the parent device 102 is connected without going through the transformer 104. Further, the server 103 recognizes the ID of the child device 101 from which the parent device 102 collects the power information, based on the power information received from the parent device 102. The ID is, for example, a MAC address.

The server 103 checks whether or not the child device 101 is in a state of establishing a communication connection with the parent device 102 via the transformer 104 based on the list to be held.

In this example, the server 103 recognizes that the child device 101A is in a state of establishing a communication connection with the parent device 102B via the transformer 104. When this state continues for a predetermined time, the predetermined condition C1 is satisfied.

Next, the server 103 transmits the created withdrawal notification to the parent device 102B (step S904).

Next, when the parent device 102B receives the withdrawal notification from the server 103, the parent device 102B transmits the received withdrawal notification to the child device 101A (step S906).

More specifically, when the processing unit 25 in the parent device 102B receives the withdrawal notification from the server 103 via the communication unit 21, the processing unit 25 transmits the withdrawal notification to the child device 101A via the communication unit 21 according to the received withdrawal notification.

Next, when the child device 101A receives the withdrawal notification from the parent device 102B, the child device 101A performs a withdrawal process of disconnecting the communication connection with the parent device 102B according to the received withdrawal notification (step S908).

Then, the child device 101A broadcasts the beacon request as shown in FIG. As a result, the child device 101A can establish a communication connection with the parent device 102C (see FIG. 8) capable of communicating without going through the transformer 104, so that the power information can be transmitted with a good success rate.

In the parent device according to the embodiment of the present invention, the processing unit 25 relates to the child device 101A that newly establishes a communication connection with the parent device 102B by relaxation processing according to the withdrawal notification received from the server 103. The configuration is such that processing for disconnecting the communication connection is performed, but the present invention is not limited to this. The processing unit 25 may be configured to disconnect the communication connection between its own parent device 102B and the child device 101A by, for example, proactively creating a withdrawal notification and transmitting it to the child device 101A.

More specifically, the processing unit 25 holds, for example, a normal time list including the MAC address of the child device 101A connected to its parent device 102B without going through the transformer 104. The contents of the normal time list are the same as those of the child device list Lst1 (see FIG. 10) at the timing before the parent device 102 is stopped (step S302 shown in FIG. 11). For example, the processing unit 25 extracts the MAC addresses included in the child device list Lst1 that are not included in the normal time list after a lapse of a predetermined time from the relaxation process. The processing unit 25 transmits a withdrawal notification to the child device 101 having the extracted MAC address via the communication unit 21. Here, the predetermined time is calculated based on, for example, the time required for replacement of the parent device 102A.

Further, in the parent device according to the embodiment of the present invention, the processing unit 25 performs a process for disconnecting the communication connection of the child device 101A newly established a communication connection with the parent device 102B by the relaxation process. Although it is said that the configuration is to be performed, the configuration is not limited to this. For example, the communication connection between the parent device 102B and the child device 101A may be disconnected by the administrator turning off or resetting the power of the child device 101A.

Further, in the electric power information collecting system according to the embodiment of the present invention, as shown in FIG. 19, the child device 101 that has received the allocation processing of the electric power information transmission period Pp transmits in two consecutive electric power information transmission periods. It is assumed that the power information to be power is transmitted in one assigned power information transmission period, but the present invention is not limited to this. The child device 101 that has received the power information transmission period Pp allocation process transmits one of the power information to be transmitted in each of the two consecutive power information transmission periods in one assigned power information transmission period. It may be configured to be used.

By the way, in the communication network described in Patent Document 1, for example, a plurality of master units may be provided. In such a communication network, the master unit manages a plurality of slave units, and periodically acquires power information from the slave units managed by the master unit. For example, if one of the plurality of master units fails, the slave unit under the control of the failed master unit tries to enter the control of the other master unit. However, if there is an upper limit to the number of slave units that can be managed by the master unit, other master units may not be able to manage the slave units that are going to be under their control. In such a situation, the power information from the slave unit that is not under the control of the master unit is lost, which is not preferable.

On the other hand, the parent device according to the embodiment of the present invention communicates with the child device 101 via the power line 161. The counting unit 22 counts the requested number of child devices 101 requesting a communication connection with its own parent device 102 and the number of connected child devices 101 having established a communication connection. Then, the processing unit 25 counts by the counting unit 22 when its own parent device 102 is operating in a state where the number of connectable devices 101, which is the number of child devices 101 capable of establishing a communication connection, is limited to a predetermined value. When the sum of the requested number of units and the number of connected units exceeds the predetermined value, mitigation processing is performed to increase the number of connectable units.

With such a configuration, for example, the number of child devices 101 trying to come under the control of the own parent device 102 due to the failure of another parent device 102 increases, and the sum of the requested number and the number of connected devices becomes a predetermined value. Even if it exceeds the limit, the number of connectable units can be increased. As a result, it is possible to establish a communication connection with the child device 101 that is about to enter the control of its own parent device 102, so that the child device loses the transmission destination of the power information because it cannot be placed under the control of the parent device 102. It is possible to prevent 101 from occurring. Therefore, in a system including a plurality of slave units, the slave units can be managed satisfactorily. As a result, it is possible to prevent the power information from the child device 101 that is not under the control of the parent device 102 from being lost.

Further, in the parent device according to the embodiment of the present invention, the processing unit 25 performs a process for disconnecting the communication connection with the child device 101 newly established by the relaxation process.

With such a configuration, for example, when a new parent device 102 is provided in place of another failed parent device 102, the child device 101 that newly establishes a communication connection with its own parent device 102 by relaxation processing On the other hand, it is possible to establish a communication connection with the new parent device 102 capable of performing better communication.

Further, in the parent device according to the embodiment of the present invention, the parent device 102 and each child device 101 having established a communication connection transmit and receive information in a periodically repeated information period. The information period includes the power information transmission period Pp for the child device 101 to transmit the power information. Then, the processing unit 25 performs a process of extending the power information transmission period Pp as a relaxation process.

For example, when the length of the power information transmission period Pp is set according to the number of connectable devices before the relaxation process is performed, the power information from the number of child devices 101 exceeding a predetermined value is transmitted in the power information transmission period Pp. It can be difficult to do. With the above configuration, power information from a number of slave devices 101 exceeding a predetermined value can be transmitted during the power information transmission period Pp.

Further, in the parent device according to the embodiment of the present invention, the parent device 102 and each child device 101 having established a communication connection transmit and receive information in a periodically repeated information period. The information period includes the power information transmission period Pp for the child device 101 to transmit the power information. Then, as a relaxation process, the processing unit 25 causes a part of each child device 101 that exceeds the predetermined value in the power information transmission period Pp of one of the two continuous power information transmission periods Pp to transmit the power information. In the other power information transmission period Pp, the power information is transmitted to the rest of each child device 101 that exceeds the predetermined value.

For example, when the length of the power information transmission period Pp is set according to the number of connectable devices before the relaxation process is performed, the power information from the number of child devices 101 exceeding a predetermined value is transmitted in the power information transmission period Pp. It can be difficult to do. With the above configuration, the number of child devices 101 exceeding a predetermined value can obtain an opportunity to transmit power information in one of two consecutive power information transmission periods Pp, so that the power information transmission destination can be set. It is possible to prevent it from being left in a lost state.

It should be considered that the above embodiments are exemplary in all respects and not restrictive. The scope of the present invention is shown by the scope of claims rather than the above description, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims.

The above description includes the features described below.

[Appendix 1]
A parent device that communicates with a power information acquisition device via a power line.
A count that counts the number of requested power information acquisition devices that are requesting a communication connection with its own parent device, and the number of connections that is the number of power information acquisition devices that have established the communication connection. Department and
When the parent device of its own is operating in a state where the number of connectable units, which is the number of power information acquisition devices capable of establishing the communication connection, is limited to a predetermined value, the request counted by the counting unit. When the sum of the number of units and the number of connected units exceeds the predetermined value, a processing unit that performs relaxation processing for increasing the number of connectable units is provided.
The power information acquisition device is a smart meter.
The parent device is a parent device that is a concentrator.

10 Internet 21 Communication unit 22 Counting unit 24 Storage unit 25 Processing unit 71 MAC frame 101 Child device 102 Parent device 103 Server 104 Transformer 151 Apartment house 161 Power line 171 Power system 301 Power information collection system

Claims (6)

A parent device that communicates with a power information acquisition device via a power line.
A count that counts the number of requested power information acquisition devices that are requesting a communication connection with its own parent device, and the number of connections that is the number of power information acquisition devices that have established the communication connection. Department and
When the parent device of its own is operating in a state where the number of connectable units, which is the number of power information acquisition devices capable of establishing the communication connection, is limited to a predetermined value, the request counted by the counting unit. A parent device including a processing unit that performs relaxation processing for increasing the predetermined value when the sum of the number of units and the number of connected units exceeds the predetermined value. Wherein the processing unit is further, after establishing the communication connection with the relaxation treatment Shin was Do the power information acquisition device by, if satisfying predetermined conditions including a predetermined time elapses, and the new power information acquisition device The parent device according to claim 1, wherein the process for disconnecting the communication connection is performed. The parent device according to claim 2, wherein the predetermined condition includes a state in which the power information acquisition device establishes a communication connection with the parent device via a transformer for a predetermined time. The parent device and each of the power information acquisition devices that have established the communication connection transmit and receive information during an information period that is periodically repeated.
The information period includes a power information transmission period for the power information acquisition device to transmit power information.
The parent device according to any one of claims 1 to 3, wherein the processing unit performs a process of extending the power information transmission period as the relaxation process. The parent device and each of the power information acquisition devices that have established the communication connection transmit and receive information during an information period that is periodically repeated.
The information period includes a power information transmission period for the power information acquisition device to transmit power information.
As the relaxation process, the processing unit supplies the electric power to a part of each electric power information acquisition device that exceeds the predetermined value before the change in the electric power information transmission period of one of the two continuous electric power information transmission periods. According to any one of claims 1 to 3 , the information is transmitted, and the power information is transmitted to the rest of the power information acquisition devices that exceed the predetermined value before the change in the other power information transmission period. The parent device described. A communication control method in a parent device that communicates with a power information acquisition device via a power line.
A step of counting the requested number of power information acquisition devices requesting a communication connection with its own parent device and the number of connections which are the number of power information acquisition devices having established the communication connection. When,
When the parent device of its own is operating in a state where the number of connectable units, which is the number of power information acquisition devices capable of establishing the communication connection, is limited to a predetermined value, the counted number of requested units and the number of connected units are counted. A communication control method including a step of performing a relaxation process for increasing the predetermined value when the sum of the above exceeds the predetermined value.

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