JP2017034468A - Communication method, control device using the same and communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique of efficiently changing a frequency channel used for communication.SOLUTION: A communication unit 40 uses one frequency channel out of a plurality of frequency channels. When a communication unit 40 receives a connection authentication request signal from a radio device and permits connection of the radio device, a controller 46 causes the communication unit 40 to transmit a connection authentication permission signal to the radio device. A channel changing unit 42 changes one frequency channel used in the channel changing unit 42 to different one frequency channel. Further, in a case where the channel changing unit 42 starts the processing for changing the frequency channel, the controller 46 transmits a connection authentication rejection signal from the communication unit 40 to the radio device even if the communication unit 40 receives the connection authentication request signal from the radio device.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a communication technique, and more particularly, to a communication method using a plurality of frequency channels, a control device using the same, and a communication system.

  In short-range wireless communication called wireless PAN (Personal Area Network), home appliances and the like in a home are connected via a wireless network, whereby information is exchanged between the devices. As the wireless PAN, for example, standardized standards such as IEEE 802.15.4 are known. In a typical usage scene, a single control device and a plurality of terminal devices such as home appliances are installed in one household, and a plurality of terminal devices are connected in a star shape with a focus on the control device. (See, for example, Patent Document 1).

International Publication No. 12/124339 Pamphlet

  A plurality of frequency channels that can be used for communication between the control device and the terminal device are provided, and the control device selects one of them and uses it for communication with the terminal device. The control device can also change one frequency channel to be used. For example, the control device disconnects links with all connected terminal devices, and then changes the frequency channel. On the other hand, the terminal device whose link has been disconnected performs frequency channel scanning by itself and attempts to reconnect to the control device using a new frequency channel. It is desirable that such a frequency channel change be made efficiently.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a technique for efficiently changing a frequency channel used for communication.

  In order to solve the above problem, a control device according to an aspect of the present invention includes a communication unit that uses one frequency channel among a plurality of frequency channels, and the communication unit receives a connection authentication request signal from the wireless device, In addition, when permitting connection of the wireless device, a control unit that transmits a connection authentication permission signal from the communication unit to the wireless device, and a channel change that changes one frequency channel used in the communication unit to another frequency channel. A part. When the channel changing unit starts processing for changing the frequency channel, the control unit transmits a connection authentication rejection signal from the communication unit to the wireless device even if the communication unit receives the connection authentication request signal from the wireless device. Let

  Another aspect of the present invention is a communication system. The communication system includes a control device and a wireless device that can be connected to the control device. The control device permits connection authentication when a communication unit that uses one of a plurality of frequency channels and the communication unit receives a connection authentication request signal from the wireless device and permits connection of the wireless device. A control unit that transmits a signal from the communication unit to the wireless device, and a channel change unit that changes one frequency channel used in the communication unit to another frequency channel. When the channel changing unit starts processing for changing the frequency channel, the control unit transmits a connection authentication rejection signal from the communication unit to the wireless device even if the communication unit receives the connection authentication request signal from the wireless device. Let

  Yet another embodiment of the present invention is a communication method. This method uses a frequency channel of a plurality of frequency channels, and receives a connection authentication request signal from a wireless device and permits connection of the wireless device, and transmits the connection authentication permission signal to the wireless device. A connection authentication request signal is received from the wireless device when a process for changing one frequency channel used to another frequency channel and a process for changing the frequency channel is started. The step of transmitting a connection authentication rejection signal to the wireless device.

  It should be noted that any combination of the above-described constituent elements and a conversion of the expression of the present invention between a method, an apparatus, a system, a recording medium, a computer program, etc. are also effective as an aspect of the present invention.

  According to the present invention, the frequency channel used for communication can be changed efficiently.

It is a figure which shows the structure of the communication system which concerns on the Example of this invention. It is a sequence diagram which shows the channel change procedure by the communication system used as the comparison object of the communication system of FIG. It is a sequence diagram which shows another channel change procedure by the communication system used as the comparison object of the communication system of FIG. It is a figure which shows the structure of the control apparatus of FIG. It is a figure which shows the data structure of the table memorize | stored in the memory | storage part of FIG. It is a sequence diagram which shows the channel change procedure by the communication system of FIG. It is a sequence diagram which shows another channel change procedure by the communication system of FIG. It is a sequence diagram which shows another channel change procedure by the communication system of FIG. It is a sequence diagram which shows another channel change procedure by the communication system of FIG. It is a flowchart which shows the channel change procedure by the control apparatus of FIG. It is a sequence diagram which shows the connection authentication procedure by the communication system of FIG.

  Before describing the present invention in detail, an outline will be described. An embodiment of the present invention relates to a communication system that communicates using any one of a plurality of frequency channels. As described above, the selection and change of one frequency channel to be used is made by the controller. At that time, the links with all the terminal devices connected so far are disconnected. On the other hand, the terminal device cannot understand that the reason for the link disconnection by the control device is the frequency channel. Therefore, even before the control device changes the frequency channel, the terminal device may start a frequency channel scan for reconnection, and the control device and the terminal device may be reconnected. As a result, it is necessary for the control device to disconnect the link with the terminal device again. Furthermore, when a packet signal is transmitted between the control device and the terminal device for reconnection and re-disconnection, traffic increases, and packet signals collide and communication errors easily occur. Therefore, it is desirable to efficiently change the frequency channel used for communication.

  To cope with this, when starting the frequency channel changing process, the control device according to the present embodiment disconnects the connected terminal device and rejects the connection of the unconnected terminal device. In the communication system, in order to increase the communication distance between the control device and the terminal device, a relay device is arranged between the control device and the terminal device, and the control device and the terminal device are connected via the relay device. Communication may be performed. At that time, the control device, the relay device, and the terminal device share one of a plurality of frequency channels. Under such circumstances, when changing the frequency channel, the control device also disconnects the link with the relay device. More specifically, the control device disconnects the link with the terminal device connected to the relay device, and then connects the link with the relay device. In the control device, the connection / disconnection processing for the relay device is performed in the same manner as the connection / disconnection processing for the terminal device. Therefore, the relay device and the terminal device may be collectively referred to as “wireless device”.

  FIG. 1 shows a configuration of a communication system 100 according to an embodiment of the present invention. The communication system 100 includes a control device 10, a first terminal device 12 a collectively referred to as a terminal device 12, a second terminal device 12 b, a relay device 14, a smart meter 16, and a collection control station 18. The control device 10, the terminal device 12, the relay device 14, and the smart meter 16 are installed in a house 28. In FIG. 1, only one house 28 is shown for the sake of clarity, but actually, there are a plurality of houses 28, and each house 28 has a smart meter 16, a control device 10, a relay. A device 14 and a terminal device 12 are installed.

  The collection control station 18, the smart meter 16, the control device 10, the terminal device 12, and the relay device 14 all have a wireless communication function. The wireless communication between the collection control station 18 and the smart meter 16 is a multi-hop communication 26, and the wireless communication between the smart meter 16 and the control device 10 is an upper communication 24. In addition, wireless communication between the control device 10 and the relay device 14, wireless communication between the relay device 14 and the second terminal device 12b, and wireless communication between the control device 10 and the first terminal device 12a are HAN communication 22 It is. The multi-hop communication 26 is realized by transfer by the smart meter 16 installed in each house 28, and corresponds to an A route of Wi-SUN (Wireless Smart Utility Networks). The host communication 24 corresponds to the Wi-SUN B route, and the HAN communication 22 corresponds to a Wi-SUN HAN (Home Area Network). These correspond to, for example, IEEE 802.15.4, but are not limited thereto.

  The smart meter 16 has a function as a power meter that measures the amount of power used in the house 28 in addition to the wireless communication function described above. The smart meter 16 is connected to a distribution line (not shown) that is supplied with commercial power from an electric power company (electricity provider), and measures the amount of power used in the house 28. Since a known technique may be used for this function, description thereof is omitted here. The smart meter 16 transmits the meter reading data including the measurement result of the electric energy to the collection control station 18 through the multihop communication 26. The collection control station 18 receives meter reading data from the smart meter 16. This allows remote meter reading by the power company.

  The terminal device 12 is connected to an electronic device (not shown) installed in the house 28. The electronic device is, for example, an air conditioner, an OA device, or a television receiver. The first terminal device 12 a corresponds to the HAN communication 22 and communicates with the control device 10. The relay device 14 corresponds to the HAN communication 22 and relays communication between the control device 10 and the second terminal device 12b by communicating with the control device 10 and the second terminal device 12b. Note that the second terminal device 12 b also corresponds to the HAN communication 22. The control device 10 is connected to or mounted on an electronic device such as a HEMS (Home Energy Management System) controller, for example. The control device 10 also communicates with the smart meter 16 via the host communication 24, and therefore receives the measurement result from the smart meter 16. The measurement result enables accurate power management in the electronic device.

  In the HAN communication 22, a plurality of frequency channels are frequency-multiplexed. The bandwidth of one frequency channel is 400 kHz, for example. The control device 10 selects and uses one frequency channel among a plurality of frequency channels. The first terminal device 12a, the second terminal device 12b, and the relay device 14 use one frequency channel selected by the control device 10. In the HAN communication 22, CSMA / CA (Carrier Sense Multiple Access / Collision Aidance) is executed by the control device 10, the first terminal device 12a, the second terminal device 12b, and the relay device 14. The transmission rate of the HAN communication 22 is, for example, 100 kbps.

  Here, in order to clarify the subject of a present Example, the channel change procedure by the communication system used as the comparison object of the communication system 100 is demonstrated. The communication system to be compared is configured in the same manner as in FIG. 1, but the control device 10, the terminal device 12, and the relay device 14 in FIG. 1 are indicated as the control device 110, the terminal device 112, and the relay device 114. As a premise, the control device 110 registers information on the terminal device 112 and the relay device 114 that can communicate with each other, and when changing the frequency channel, deletes the registered information on the terminal device 112 and the relay device 114. The number of frequency channels is “N”.

  FIG. 2 is a sequence diagram illustrating a channel change procedure by a communication system to be compared with the communication system 100. Here, for the sake of clarity, it is assumed that only the first terminal device 112 a is registered in the control device 110. The control device 110 starts the channel change process under the situation where the frequency channel “1ch” is used (S10). The control device 110 transmits a disconnection request signal to the first terminal device 112a (S12). The first terminal device 112a transmits a disconnection response signal to the control device 110 (S14) and disconnects. The control device 110 updates the storage unit so as to delete the information of the first terminal device 112a (S16). The first terminal apparatus 112a starts reconnection (S18). The first terminal apparatus 112a transmits a beacon request signal on the frequency channel “1ch” (S20). In addition, the first terminal apparatus 112a transmits a beacon request signal on the frequency channel “Nch” (S22). The control device 110 transmits a beacon signal on the frequency channel “1ch” (S24).

  The first terminal device 112a transmits a connection authentication request signal to the control device 110 (S26). The control device 110 permits connection authentication of the first terminal device 112a (S28), and updates the storage unit so as to register information of the first terminal device 112a (S30). The control device 110 transmits a connection authentication permission signal to the first terminal device 112a (S32). The control device 110 transmits a disconnection request signal to the first terminal device 112a (S34). The first terminal device 112a transmits a disconnection response signal to the control device 110 (S36) and disconnects. The control device 110 updates the storage unit so as to delete the information of the first terminal device 112a (S38). The control device 110 changes the frequency channel (S40).

  The control device 110 deletes the link with the first terminal device 112a in order to execute the channel change process. However, before the channel change process is executed, when the first terminal device 112a is connected, the control device 110 must delete the link with the first terminal device 112a again. Therefore, it can be said that the processing from step 20 to step 38 in FIG. 2 is useless processing. Of these steps, the number of steps to be performed should be reduced in order to change the frequency channel efficiently.

  FIG. 3 is a sequence diagram illustrating another channel change procedure by the communication system to be compared with the communication system 100. Here, for the sake of clarity, it is assumed that only the relay device 114 and the second terminal device 112b are registered in the control device 110. The control device 110 starts the channel change process under the situation where the frequency channel “1ch” is used (S50). The control device 110 transmits a disconnection request signal to the second terminal device 112b via the relay device 114 (S52, S54). The second terminal device 112b transmits a disconnection response signal to the control device 110 via the relay device 114 (S56, S58) and disconnects. The control device 110 updates the storage unit so as to delete the information of the second terminal device 112b (S60). The second terminal device 112b starts reconnection (S62). The second terminal apparatus 112b transmits a beacon request signal on the frequency channel “1ch” (S64). In addition, the second terminal apparatus 112b transmits a beacon request signal on the frequency channel “Nch” (S66). The relay device 114 transmits a beacon signal on the frequency channel “1ch” (S68).

  The second terminal device 112b transmits a connection authentication request signal to the control device 110 via the relay device 114 (S70, S72). The control device 110 permits connection authentication of the second terminal device 112b (S74), and updates the storage unit so as to register information of the second terminal device 112b (S76). The control device 110 transmits a connection authentication permission signal to the second terminal device 112b via the relay device 114 (S78, S80). The control device 110 transmits a disconnection request signal to the second terminal device 112b via the relay device 114 (S82, S84). The second terminal device 112b transmits a disconnection response signal to the control device 110 via the relay device 114 (S86, S88) and disconnects. The control device 110 updates the storage unit so as to delete the information of the second terminal device 112b (S90). The control device 110 transmits a disconnection request signal to the relay device 114 (S92). The relay device 114 transmits a disconnection response signal to the control device 110 (S94) and disconnects. The control device 110 changes the frequency channel (S96).

  As in the case of FIG. 2, the control device 110 deletes the link with the second terminal device 112b and the relay device 114 in order to execute the channel change process. However, before the channel change process is executed, when the second terminal apparatus 112b is connected, the control apparatus 110 must delete the link with the second terminal apparatus 112b again. Therefore, it can be said that the processing from step 64 to step 90 in FIG. Of these steps, the number of steps to be performed should be reduced in order to change the frequency channel efficiently.

  FIG. 4 shows the configuration of the control device 10. The control device 10 includes a communication unit 40, a channel change unit 42, a data processing unit 44, a control unit 46, and a storage unit 52. The communication unit 40 includes a reception unit 48 and a transmission unit 50, the data processing unit 44 includes an application processing unit 60, and the control unit 46 includes a disconnection processing unit 54, a connection processing unit 56, and a determination unit 58.

  The communication unit 40 executes communication with the terminal device 12 and the relay device 14 by executing processing corresponding to the HAN communication 22, and performs processing corresponding to the upper communication 24 with the smart meter 16. Execute communication. Here, for the HAN communication 22, the communication unit 40 uses one frequency channel among a plurality of frequency channels. One frequency channel used in the communication unit 40 is designated by the channel changing unit 42. On the other hand, for the higher level communication 24, the communication unit 40 uses one frequency channel among a plurality of frequency channels, and the one frequency channel is the same as one frequency channel used in the HAN communication 22. It may be different or different. One frequency channel used in the host communication 24 is determined by the smart meter 16. Below, it demonstrates centering on the HAN communication 22, and description of the high-order communication 24 is abbreviate | omitted.

  The receiving unit 48 receives a packet signal from the first terminal device 12a and also receives a packet signal from the second terminal device 12b via the relay device 14. The receiving unit 48 has an amplification function, a frequency conversion function, and a demodulation function, and generates a baseband signal from the received packet signal. The receiving unit 48 outputs the baseband signal to the data processing unit 44 and the control unit 46. The transmission unit 50 has a modulation function, a frequency conversion function, and an amplification function, and generates a packet signal from the baseband signal input from the data processing unit 44 and the control unit 46. The transmission unit 50 transmits a packet signal to the first terminal device 12a and transmits the packet signal to the second terminal device 12b via the relay device 14.

  The communication path of such a packet signal is stored in the storage unit 52 as a routing table, and the reception unit 48 and the transmission unit 50 refer to the routing table stored in the storage unit 52. FIG. 5 shows the data structure of the table stored in the storage unit 52. This can also be said to be information regarding the registered terminal device 12 and relay device 14. The “device MAC address” shown in the figure indicates a MAC address of “device type”. Further, “device type” and “connection destination” indicate a connection relationship of devices. Specifically, the first terminal device 12a and the relay device 14 of “device type” are connected to the control device 10 of “connection destination”, and the second terminal device 12b of “device type” is “connection destination”. Connected to the relay device 14. Returning to FIG.

  The terminal device 12 and the relay device 14 shown in the routing table are registered after being authenticated in advance in order to ensure security. For the authentication process, a known technique may be used. For example, a PANA (Protocol for Carrying Authentication) standard communication protocol is used. As the start of the authentication process, the receiving unit 48 receives a connection authentication request signal from a new terminal device 12 or relay device 14. The receiving unit 48 outputs the received connection authentication request signal to the connection processing unit 56. The connection processing unit 56 executes an authentication process, and outputs a connection authentication permission signal to the transmission unit 50 when the connection of the new terminal device 12 or the relay device 14 is permitted. In addition, the connection processing unit 56 stores information on the new terminal device 12 or the relay device 14 in the storage unit 52. The transmission unit 50 transmits a connection authentication permission signal to the new terminal device 12 or the relay device 14. Thus, the terminal device 12 and the relay device 14 registered in the control device 10 can communicate with the control device 10.

  When the baseband signal from the reception unit 48 is input, the data processing unit 44 processes the baseband signal. On the other hand, the data processing unit 44 generates a baseband signal when data to be transmitted occurs. If the reception unit 48 has not received the packet signal, the data processing unit 44 outputs the baseband signal to the transmission unit 50.

  The application processing unit 60 executes an arbitrary application program. The application processing unit 60 receives a trigger for a frequency channel change request from the application program being executed. The control device 10 may include a user interface (not shown), and the application processing unit 60 may receive a frequency channel change request trigger from the user via the user interface. The application processing unit 60 outputs a frequency channel change request trigger to the channel change unit 42.

  The channel change unit 42 inputs a frequency channel change request trigger from the application processing unit 60. As described above, when the control device 10 changes the frequency channel, the registered information on the terminal device 12 and the relay device 14 must be deleted. Therefore, the channel changing unit 42 instructs the disconnection processing unit 54 to disconnect the terminal device 12 and the relay device 14 registered in the storage unit 52.

  The disconnection processing unit 54 receives a disconnection instruction from the channel changing unit 42, that is, when the channel changing unit 42 starts processing for changing the frequency channel, the terminal device 12 to be disconnected from the storage unit 52. The information of the relay device 14 is acquired. The cutting processing unit 54 generates a cutting request signal by setting a destination based on the acquired information. The disconnection processing unit 54 transmits a disconnection request signal from the transmission unit 50 to the terminal device 12 or the relay device 14.

  The receiving unit 48 receives from the terminal device 12 or the relay device 14 a disconnection response signal for the disconnection request signal transmitted by the transmitting unit 50 after the channel changing unit 42 starts processing for changing the frequency channel. The receiving unit 48 outputs a disconnection response signal to the disconnection processing unit 54. The disconnection processing unit 54 receives the disconnection response signal from the reception unit 48. Accordingly, since it can be said that the disconnection of the terminal device 12 or the relay device 14 is completed, the disconnection processing unit 54 deletes the information of the terminal device 12 or the relay device 14 that has been disconnected from the storage unit 52. When there are a plurality of terminal devices 12 and relay devices 14 to be disconnected, the disconnection processing unit 54 executes such processing for each terminal device 12 or relay device 14. At that time, when the terminal device 12 is connected to the relay device 14, the disconnection processing unit 54 executes the disconnection processing for the terminal device 12 and then the disconnection processing for the relay device 14.

  Even under such circumstances, when receiving the connection authentication request signal from the terminal device 12 or the relay device 14, the receiving unit 48 outputs the connection authentication request signal to the connection processing unit 56. When the channel change unit 42 starts processing for changing the frequency channel and receives a connection authentication request signal, the connection processing unit 56 rejects the connection of the terminal device 12 or the relay device 14. The connection processing unit 56 outputs a connection authentication rejection signal to the transmission unit 50 when the connection is rejected. The transmitting unit 50 transmits a connection authentication rejection signal to the terminal device 12 or the relay device 14. Here, this process will be described in more detail.

  The determination unit 58 stores information on the terminal device 12 or the relay device 14 that is the transmission source of the connection authentication request signal received by the reception unit 48 when the channel change unit 42 starts processing for changing the frequency channel. Whether it is stored in the unit 52 or not is confirmed. If information regarding the terminal device 12 or the relay device 14 is not stored in the storage unit 52, the determination unit 58 causes the connection processing unit 56 to output a connection authentication rejection signal. On the other hand, if information related to the terminal device 12 or the relay device 14 is stored in the storage unit 52, the determination unit 58 causes the connection processing unit 56 to output a connection authentication rejection signal and information related to the terminal device 12 or the relay device 14. Is deleted from the storage unit 52. In any of these cases, the connection processing unit 56 receives a connection authentication request signal from a period (for example, a set value of 5 seconds) until the processing with the terminal device 12 or the relay device 14 times out. Alternatively, the connection authentication rejection signal may be output to the transmitter 50 after waiting for a short period.

  The channel changing unit 42 is used in the communication unit 40 when the information stored in the storage unit 52 has been deleted, that is, when all the terminal devices 12 or relay devices 14 stored in the storage unit 52 have been deleted. Change one frequency channel to another frequency channel. In that case, the channel change part 42 may perform a carrier sense via the communication part 40, and may select the frequency channel with the smallest interference power. Further, the channel changing unit 42 may select the frequency channel so as to avoid the frequency channel used in the upper communication 24. The channel changing unit 42 controls the communication unit 40 so as to switch to one frequency channel after the change.

  This configuration can be realized in terms of hardware by a CPU, memory, or other LSI of any computer, and in terms of software, it can be realized by a program loaded in the memory, but here it is realized by their cooperation. Draw functional blocks. Accordingly, those skilled in the art will understand that these functional blocks can be realized in various forms only by hardware, or by a combination of hardware and software.

  The operation of the communication system 100 configured as above will be described. FIG. 6 is a sequence diagram showing a channel change procedure by the communication system 100. Here, for the sake of clarity, it is assumed that only the first terminal device 12a is registered in the control device 10. The control device 10 starts the channel change process under the situation where the frequency channel “1ch” is used (S100). The control device 10 transmits a disconnection request signal to the first terminal device 12a (S102). The first terminal apparatus 12a transmits a disconnection response signal to the control apparatus 10 (S104) and disconnects. The control device 10 updates the storage unit 52 so as to delete the information of the first terminal device 12a (S106). The first terminal apparatus 12a starts reconnection (S108).

  The first terminal apparatus 12a transmits a beacon request signal on the frequency channel “1ch” (S110). The first terminal apparatus 12a transmits a beacon request signal on the frequency channel “Nch” (S112). The control device 10 transmits a beacon signal on the frequency channel “1ch” (S114). The first terminal device 12a transmits a connection authentication request signal to the control device 10 (S116). The control device 10 rejects connection authentication of the first terminal device 12a (S118). The control device 10 transmits a connection authentication rejection signal to the first terminal device 12a (S120). The control device 10 executes frequency channel change (S122).

  FIG. 7 is a sequence diagram showing another channel change procedure by the communication system 100. Here, for the sake of clarity, it is assumed that only the relay device 14 and the second terminal device 12b are registered in the control device 10. The controller 10 starts the channel change process under the situation where the frequency channel “1ch” is used (S150). The control device 10 transmits a disconnection request signal to the second terminal device 12b via the relay device 14 (S152, S154). The second terminal apparatus 12b transmits a disconnection response signal to the control apparatus 10 via the relay apparatus 14 (S156, S158) and disconnects. The control device 10 updates the storage unit 52 so as to delete the information of the second terminal device 12b (S160). The second terminal device 12b starts reconnection (S162). The second terminal apparatus 12b transmits a beacon request signal on the frequency channel “1ch” (S164). Further, the second terminal apparatus 12b transmits a beacon request signal on the frequency channel “Nch” (S166). The relay device 14 transmits a beacon signal on the frequency channel “1ch” (S168).

  The second terminal device 12b transmits a connection authentication request signal to the control device 10 via the relay device 14 (S170, S172). The control device 10 rejects the connection authentication of the second terminal device 12b (S174). The control device 10 transmits a connection authentication rejection signal to the second terminal device 12b via the relay device 14 (S176, S178). The control device 10 transmits a disconnection request signal to the relay device 14 (S180). The relay device 14 transmits a disconnection response signal to the control device 10 (S182) and disconnects. The control apparatus 10 performs a frequency channel change (S184).

  FIG. 8 is a sequence diagram showing still another channel change procedure by the communication system 100. Here, for the sake of clarity, it is assumed that only the first terminal device 12a is registered in the control device 10. The control apparatus 10 starts the channel change process under the situation where the frequency channel “1ch” is used (S200). The first terminal device 12a transmits a connection authentication request signal to the control device 10 (S202). The control device 10 rejects the connection authentication of the first terminal device 12a (S204), and updates the storage unit 52 to delete the information of the first terminal device 12a (S206). The control device 10 transmits a connection authentication rejection signal to the first terminal device 12a (S208). The control device 10 executes frequency channel change (S210).

  FIG. 9 is a sequence diagram showing still another channel change procedure by the communication system 100. Here, for the sake of clarity, it is assumed that only the relay device 14 and the second terminal device 12b are registered in the control device 10. The controller 10 starts the channel change process under the situation where the frequency channel “1ch” is used (S250). The second terminal device 12b transmits a connection authentication request signal to the control device 10 via the relay device 14 (S252, S254). The control device 10 rejects the connection authentication of the second terminal device 12b (S256), and updates the storage unit 52 to delete the information of the second terminal device 12b (S258). The control device 10 transmits a connection authentication rejection signal to the second terminal device 12b via the relay device 14 (S260, S262). The control device 10 transmits a disconnection request signal to the relay device 14 (S264). The relay device 14 transmits a disconnection response signal to the control device 10 (S266) and disconnects. The control device 10 executes frequency channel change (S268).

  FIG. 10 is a flowchart showing a channel change procedure by the control device 10. The cutting processing unit 54 refers to the storage unit 52 (S300), and causes the transmitting unit 50 to transmit a cutting request signal (S302). If the transmission unit 50 does not receive a packet signal (N in S304), the process waits. If the transmission unit 50 receives the packet signal (Y in S304) and is a disconnection response signal (Y in S306), the disconnection processing unit 54 deletes and updates the storage unit 52 (S308). If the deletion is not completed (N in S310), the process returns to step 302. If the deletion is completed (Y in S310), the channel changing unit 42 executes the channel change (S312).

  When it is not a disconnection response signal (N in S306) but a connection authentication request signal (Y in S314) and information on the terminal device 12 or the relay device 14 is stored in the storage unit 52 (Y in S316), connection processing The unit 56 deletes and updates the storage unit 52 (S318), and causes the transmission unit 50 to transmit a connection authentication rejection signal (S320). When the information on the terminal device 12 or the relay device 14 is not stored in the storage unit 52 (N in S316), the connection processing unit 56 causes the transmission unit 50 to transmit a connection authentication rejection signal (S320). Thereafter, the process returns to step 304. If it is not a connection authentication request signal (N in S314), the data processing unit 44 executes a reception process (S322) and returns to Step 304.

  FIG. 11 is a sequence diagram showing a connection authentication procedure by the communication system 100. This corresponds to a connection authentication procedure using a PANA standard communication protocol. The first terminal device 12a transmits a client start to the control device 10 (S350). The control device 10 transmits a first authentication request to the first terminal device 12a (S352). The first terminal device 12a transmits a first authentication answer to the control device 10 (S354). The control device 10 transmits a second authentication request to the first terminal device 12a (S356). The first terminal device 12a transmits a second authentication answer to the control device 10 (S358). The control device 10 transmits a third authentication request to the first terminal device 12a (S360). The first terminal apparatus 12a transmits a third authentication answer to the control apparatus 10 (S362).

  The control device 10 derives values of the authentication counter and the output frame counter (S364). The control device 10 transmits a fourth authentication request to the first terminal device 12a (S366). The first terminal device 12a transmits a fourth authentication answer to the control device 10 (S368). The control device 10 sets an input frame counter (S370). The first terminal apparatus 12a sets the MAC key (S372), sets an authentication (output) counter (S374), and sets an input frame counter (S376). Here, the client start corresponds to the above-described connection authentication request signal. For the control device 10, a period from when the client start is received to when the process of transmitting each authentication request times out is determined. The control device 10 transmits each authentication request within a range shorter than that period and with delay, and finally refuses the connection.

  According to this embodiment, when processing for changing a frequency channel is started, even if a connection authentication request signal is received, a connection authentication rejection signal is transmitted, so that connection of a terminal device or a relay device can be avoided. . Further, since the connection of the terminal device or the relay device is avoided, the period until the terminal device or the relay device is disconnected can be shortened. In addition, since the period until the disconnection of the terminal device or the relay device is shortened, the frequency channel used for communication even when the frequency channel is changed after the disconnection of the terminal device or the relay device is completed. Can be changed efficiently.

  In addition, since the disconnection request signal is transmitted when the channel changing unit starts processing for changing the frequency channel, the terminal device or the relay device can be disconnected. In addition, when the channel changing unit starts processing for changing the frequency channel and receives a disconnection response signal for the disconnection request signal, information regarding the terminal device or the relay device is deleted from the storage unit, so that the registration can be deleted. . Also, if a connection authentication request signal is received and information related to the terminal device or relay device is not stored in the storage unit, a connection authentication rejection signal is transmitted, so disconnection is performed while confirming that it has not been registered. it can. In addition, if the connection authentication request signal is received and the information related to the information related to the terminal device or the relay device is stored in the storage unit, the connection authentication rejection signal is transmitted and the information is deleted from the storage unit. Can be deleted and disconnected.

  Further, since the frequency channel is changed when the deletion of the information stored in the storage unit is completed, the frequency channel can be changed according to the processing rule. In addition, since the connection authentication rejection signal is transmitted after waiting for a period shorter than the period until the process times out, the transmission frequency of unnecessary packet signals can be reduced.

  The outline of one embodiment of the present invention is as follows. The control device 10 according to an aspect of the present invention includes a communication unit 40 that uses one frequency channel among a plurality of frequency channels, the communication unit 40 receiving a connection authentication request signal from the wireless devices 12 and 14, and wireless communication When permitting the connection of the devices 12 and 14, the control unit 46 that transmits a connection authentication permission signal from the communication unit 40 to the wireless devices 12 and 14, and one frequency channel used in the communication unit 40 is changed to another one. And a channel changing unit 42 for changing to a frequency channel. When the channel changing unit 42 starts processing for changing the frequency channel, the control unit 46 communicates the connection authentication rejection signal even if the communication unit 40 receives the connection authentication request signal from the wireless devices 12 and 14. The transmission is performed from the unit 40 to the wireless devices 12 and 14.

  The control unit 46 may cause the communication unit 40 to transmit a disconnection request signal to the wireless devices 12 and 14 when the channel changing unit 42 starts processing for changing the frequency channel.

  You may further provide the memory | storage part 52 which memorize | stores the information regarding the registered radio | wireless apparatuses 12 and 14. FIG. The control unit 46 starts the process for the channel changing unit 42 to change the frequency channel, and when the communication unit 40 receives a disconnection response signal for the disconnection request signal from the wireless devices 12 and 14, 14 may be deleted from the storage unit 52.

  You may further provide the memory | storage part 52 which memorize | stores the information regarding the registered radio | wireless apparatuses 12 and 14. FIG. When the channel changing unit 42 starts processing for changing the frequency channel, the control unit 46 (1) the communication unit 40 receives the connection authentication request signal from the wireless devices 12 and 14, and the wireless device 12, 14 is not stored in the storage unit 52, a connection authentication rejection signal is transmitted from the communication unit 40 to the wireless devices 12 and 14, and (2) the communication unit 40 transmits a connection authentication request signal from the wireless devices 12 and 14. If the information about the wireless devices 12 and 14 is received and stored in the storage unit 52, a connection authentication rejection signal is transmitted from the communication unit 40 to the wireless devices 12 and 14, and information about the wireless devices 12 and 14 is stored. You may delete from the part 52.

  The channel changing unit 42 may change the frequency channel when the deletion of the information stored in the storage unit 52 is completed.

  The control unit 46 may cause the communication unit 40 to transmit the connection authentication rejection signal to the wireless devices 12 and 14 after waiting for a period shorter than the period until the processing with the wireless devices 12 and 14 times out.

  Another aspect of the present invention is a communication system 100. The communication system 100 includes a control device 10 and wireless devices 12 and 14 that can be connected to the control device 10. The control device 10 includes a communication unit 40 that uses one frequency channel among a plurality of frequency channels, and the communication unit 40 receives a connection authentication request signal from the wireless devices 12 and 14 and connects the wireless devices 12 and 14. A control unit 46 that transmits a connection authentication permission signal from the communication unit 40 to the wireless devices 12 and 14 and a channel that changes one frequency channel used in the communication unit 40 to another frequency channel. And a changing unit 42. When the channel changing unit 42 starts processing for changing the frequency channel, the control unit 46 communicates the connection authentication rejection signal even if the communication unit 40 receives the connection authentication request signal from the wireless devices 12 and 14. The transmission is performed from the unit 40 to the wireless devices 12 and 14.

  Yet another embodiment of the present invention is a communication method. This method uses a frequency channel of a plurality of frequency channels, and receives a connection authentication request signal from the wireless devices 12 and 14 and permits connection of the wireless devices 12 and 14. When an authentication permission signal is transmitted to the wireless devices 12 and 14, a step of changing one frequency channel to be used to another frequency channel, and a process for changing the frequency channel are started, the connection is established. A step of transmitting a connection authentication rejection signal to the wireless devices 12 and 14 even if the authentication request signal is received from the wireless devices 12 and 14.

  In the above, this invention was demonstrated based on the Example. This embodiment is an exemplification, and it will be understood by those skilled in the art that various modifications can be made to each of those constituent elements or combinations of processing processes, and such modifications are also within the scope of the present invention. .

  10 control device, 12 terminal device (wireless device), 14 relay device (wireless device), 16 smart meter, 18 collection control station, 22 HAN communication, 24 host communication, 26 multi-hop communication, 28 housing, 40 communication unit, 42 Channel change unit, 44 data processing unit, 46 control unit, 48 reception unit, 50 transmission unit, 52 storage unit, 54 disconnection processing unit, 56 connection processing unit, 58 determination unit, 60 application processing unit, 100 communication system.

Claims (8)

A communication unit that uses one of the plurality of frequency channels;
A control unit for transmitting a connection authentication permission signal from the communication unit to the wireless device when the communication unit receives a connection authentication request signal from the wireless device and permits the connection of the wireless device;
A channel changing unit that changes one frequency channel used in the communication unit to another one frequency channel;
When the channel changing unit starts processing for changing the frequency channel, the control unit sends a connection authentication rejection signal from the communication unit even if the communication unit receives a connection authentication request signal from the wireless device. A control device, characterized by causing the wireless device to transmit.   2. The control according to claim 1, wherein the control unit causes a disconnection request signal to be transmitted from the communication unit to the radio apparatus when the channel changing unit starts processing for changing a frequency channel. apparatus. A storage unit for storing information about the registered wireless device;
The control unit starts processing for changing the frequency channel by the channel changing unit, and when the communication unit receives a disconnection response signal for the disconnection request signal from the wireless device, information on the wireless device The control device according to claim 2, wherein the control unit is deleted from the storage unit. A storage unit for storing information about the registered wireless device;
When the channel changing unit starts processing for changing a frequency channel, the control unit receives (1) the communication unit receives a connection authentication request signal from a wireless device, and information on the wireless device is If not stored in the storage unit, a connection authentication rejection signal is transmitted from the communication unit to the wireless device. (2) The communication unit receives a connection authentication request signal from the wireless device, and information regarding the wireless device is present. 3. The connection authentication rejection signal is transmitted from the communication unit to the wireless device, and information related to the wireless device is deleted from the storage unit if stored in the storage unit. Control device.   The control device according to claim 3 or 4, wherein the channel change unit changes the frequency channel when the deletion of the information stored in the storage unit is completed.   2. The control unit according to claim 1, wherein the control unit causes the communication unit to transmit a connection authentication rejection signal to the wireless device after waiting for a period shorter than a period until the processing with the wireless device times out. The control device described. A control device;
A wireless device connectable to the control device,
The control device includes:
A communication unit that uses one of the plurality of frequency channels;
A control unit for transmitting a connection authentication permission signal from the communication unit to the wireless device when the communication unit receives a connection authentication request signal from the wireless device and permits the connection of the wireless device;
A channel changing unit that changes one frequency channel used in the communication unit to another one frequency channel;
When the channel changing unit starts processing for changing the frequency channel, the control unit sends a connection authentication rejection signal from the communication unit even if the communication unit receives a connection authentication request signal from the wireless device. A communication system, characterized by causing the wireless device to transmit. Using one of the plurality of frequency channels;
When receiving a connection authentication request signal from a wireless device and permitting connection of the wireless device, transmitting a connection authentication permission signal to the wireless device;
Changing one frequency channel used to another frequency channel;
A step of transmitting a connection authentication rejection signal to the wireless device even when a connection authentication request signal is received from the wireless device when processing for changing a frequency channel is started;
A communication method comprising:

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