JP2022027825A - Remote operation system and device management method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a remote operation system and a device management method, capable of appropriately managing a device when communication is interrupted.

SOLUTION: A remote operation system 100 for remotely operating a home device 10 from a server 50 installed outside a home includes: a detection module for detecting communication interruption in a communication channel that transmits control commands indicating a content of a remote operation as operation instructions to the home device 10; a state change module for changing a state of the home device 10 into a preset state if the detection module detects the communication interruption in the communication channel; a controller which inquiries, to the detection module, presence or absence of a function to detect the communication interruption in the communication channel, and, if the detection module responds that the detection module has a function to detect the communication interruption in the communication channel, sends the operation instructions to the home device 10; and an output section to start an operation of the home device 10 following the operation instructions sent by the controller.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2022,JPO&INPIT

Description

The present invention relates to a remote control system and a device management method.

In recent years, many devices having a function of connecting to a network in a house have been commercialized. Using this function, for example, the user can operate the device via the network. However, if communication via the network is interrupted for some reason, the device cannot be operated via the network. Therefore, a technique for detecting a communication interruption and recognizing that the device has become inoperable has been proposed (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2005-184781

In the system described in Patent Document 1, if communication is interrupted while the device is being operated via the network, the device may maintain the operation according to the operation before the communication is interrupted. Here, when communication is interrupted, the operation of such a device may be unfavorable for a long time. Therefore, there is a demand for proper management of equipment when communication is interrupted.

The present invention has been made in view of the above circumstances, and an object of the present invention is to appropriately manage a device when communication is interrupted.

In order to achieve the above object, the remote control system of the present invention is a remote control system for remotely controlling a home device from a server provided outside the home, and sends a control command indicating the content of the remote control to the home device. A detection unit that detects a communication interruption in the communication path transmitted as an operation instruction of, and a state change unit that changes the state of the home device to a preset state when the detection unit detects the communication interruption in the communication path. A control that inquires of the detection unit whether or not there is a function to detect communication interruption in the communication path, and sends an operation instruction to the home device when the detection unit responds that it has a function to detect the communication interruption in the communication path. It includes a unit and an output unit that starts the operation of the home device according to the operation instruction transmitted by the control unit.

According to the present invention, when communication is interrupted, the state of the home device changes. Therefore, it is possible to properly manage the equipment.

It is a figure which shows the structure of the remote control system which concerns on Embodiment 1. FIG. It is a figure which shows the structure of the home device. It is a figure which shows the structure of a device adapter. It is a figure which shows the structure of a controller. It is a flow chart which shows the device processing executed by the home device. It is a flow chart which shows the communication blackout detection processing. It is a flow chart which shows the communication recovery detection process. It is a flow diagram which shows the adapter process executed by a device adapter. It is a flow diagram which shows the controller processing executed by a controller. It is a figure which shows the example of communication from the construction of a remote control system to the completion of a remote control. It is a figure which shows the example of the case where communication is interrupted. It is a flow diagram which shows the adapter process which concerns on Embodiment 2. FIG. It is a figure which shows the example of the case where communication is interrupted.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

Embodiment 1.
FIG. 1 shows the configuration of the remote control system 100 according to the first embodiment. The remote control system 100 is a system for remotely controlling the home device 10 via a network. As shown in FIG. 1, the remote control system 100 includes a home device 10 installed in the house H1, a device adapter 20 for connecting the home device 10 to the controller 30, a controller 30 for controlling the home device 10, and the Internet. It has a connected server 50 and an operation terminal 60 for the user U1 to input the contents of the operation.

The home device 10 and the device adapter 20 are connected via a communication path 41 so as to be able to communicate with each other. The communication path 41 is, for example, a cable for performing serial communication. The communication path 41 transmits an operation instruction for operating the home device 10 from the device adapter 20 to the home device 10.

The device adapter 20 and the controller 30 are connected via a communication path 42 so that they can communicate with each other. The communication path 42 is a home network such as a wireless LAN, and transmits data according to a communication protocol such as ECHONET Lite (registered trademark). This data includes operation instructions for operating the home device 10.

The controller 30, the server 50, and the operation terminal 60 are connected to the communication path 43 so that they can communicate with each other. The communication path 43 is a wide area network such as the Internet. The communication path 43 transmits an operation instruction from the operation terminal 60 to the controller 30 via the server 50.

The home appliance 10 is an equipment or home appliance used by users U1 and U2 residing in the house H1. The home device 10 is, for example, an air conditioner that adjusts the state of air in a room in the house H1. The home device 10 may be a device (electrical device) other than the air conditioner. For example, the home appliance 10 may be a refrigerator, a television, a rice cooker, an electromagnetic cooker, a floor heater, an electric water heater, a vacuum cleaner, a microwave oven, a storage battery, or a solar generator. Further, the home equipment 10 may be other air-conditioning equipment or cooking utensils.

The home device 10 operates according to an operation instruction received via the device adapter 20 and the controller 30. For example, when the home device 10 receives an operation instruction for starting the cooling operation while the operation is stopped, the home device 10 starts the cooling operation and blows cold air from the outlet.

The operating state of the home device 10 is indicated by the value of the property in ECHONET Lite. For example, the property of the home device 10 includes an "operation mode", and the value of this "operation mode" is "heating", "cooling", "dehumidification", or "stopping". The operating state of the home device 10 changes by being set by an operation instruction.

FIG. 2 shows the configuration of the home device 10. As shown in FIG. 2, the home device 10 includes a control unit 11 that controls each component of the home device 10, a storage unit 12 that stores data, a timer 13 that measures time, and a communication path 41. It has an input unit 14 for manually operating the device 10, an output unit 15 for operating the home device 10, and a communication unit 16 for communicating via the communication path 41.

The control unit 11 is composed of, for example, a CPU (Central Processing Unit), a RAM (Random Access Memory), and the like. The control unit 11 exerts various functions by executing the program P1 stored in the storage unit 12. As its functions, the control unit 11 changes the operating state of the communication establishment module 11a for establishing communication with the device adapter 20, the detection module 11b for detecting the interruption and restoration of communication in the communication path 41, and the home device 10. It has a state change module 11c.

The storage unit 12 includes a non-volatile memory such as a hard disk or a flash memory. In addition to the program P1, the storage unit 12 stores various data used for processing by the control unit 11. This data includes a first flag F1, a second flag F2, and a third flag F3 indicating that communication in each of the communication paths 41 to 43 is interrupted.

The timer 13 is composed of, for example, a crystal oscillator or the like. The timer 13 measures the time according to the instruction of the control unit 11. Then, the timer 13 notifies the control unit 11 of the measurement result in response to the request of the control unit 11.

The input unit 14 is composed of, for example, an input key, a capacitance type pointing device, and the like. The input unit 14 acquires the operation content input by the home user U2 and transmits a signal indicating the operation content to the control unit 11.

The output unit 15 is composed of, for example, a fan for blowing air, a motor for adjusting the angle of the louver, and the like. When the home device 10 is a television, the output unit 15 is composed of, for example, a liquid crystal display, and when the home device 10 is a vacuum cleaner, the output unit 15 is a motor for sucking air. Etc.

The communication unit 16 is composed of a communication interface or the like for transmitting and receiving a data signal in a format suitable for the communication path 41. The communication unit 16 extracts data carried by this signal from the signal received via the communication path 41 and outputs the data to the control unit 11. Further, the communication unit 16 generates a signal for carrying the data output from the control unit 11 and transmits the signal via the communication path 41.

Returning to FIG. 1, the device adapter 20 is a device that relays transmission of an operation instruction or the like by converting a data signal in a format suitable for the communication path 42 into a data signal in a format suitable for the communication path 41. As shown in FIG. 3, the device adapter 20 communicates via a control unit 21 that controls each component of the device adapter 20, a storage unit 22 that stores data, a timer 23 that measures time, and a communication path 41. It has a communication unit 26 for communication and a communication unit 27 for communication via the communication path 42.

The control unit 21 is composed of, for example, a CPU, a RAM, and the like. The control unit 21 exerts various functions by executing the program P2 stored in the storage unit 22. The control unit 21 has, as its functions, a communication establishment module 21a for establishing communication with the home device 10 and the controller 30, and a detection module 21b for detecting the interruption and restoration of communication in the communication path 42.

The storage unit 22 includes a non-volatile memory such as a flash memory. In addition to the program P2, the storage unit 22 stores various data used for processing by the control unit 21.

The timer 23 is composed of, for example, a crystal oscillator or the like. The timer 23 measures the time according to the instruction of the control unit 21, and notifies the control unit 21 of the measurement result in response to the request of the control unit 21.

Each of the communication units 26 and 27 is composed of a communication interface or the like for transmitting and receiving a data signal in a format suitable for each of the communication paths 41 and 42. Each of the communication units 26 and 27 extracts the data carried by this signal from the signals received via the communication paths 41 and 42, and outputs the data to the control unit 21. Further, each of the communication units 26 and 27 generates a signal for carrying the data output from the control unit 21 and transmits the signal via each of the communication paths 41 and 42.

Returning to FIG. 1, the controller 30 is a HEMS (Home Energy Management System) controller that controls the home device 10. The controller 30 functions as a gateway server that relays the transmission of the operation instruction transmitted from the server 50 to the home device 10. For example, the controller 30 receives an operation signal indicating the content of remote control via the communication path 43. Then, the controller 30 generates a control command for controlling the home device 10 based on the content of the operation indicated by the received operation signal, and transmits the operation instruction to the home device 10 via the device adapter 20. ..

As shown in FIG. 4, the controller 30 has a control unit 31 that controls each component of the controller 30, a storage unit 32 that stores data, a timer 33 that measures time, and information input by the administrator of the controller 30. The input unit 34 for acquiring the data, the output unit 35 for presenting information to the administrator, the in-home communication unit 36 for communicating via the communication path 42, and the out-of-home communication for communicating via the communication path 43. It has a part 37.

The control unit 31 is composed of, for example, a CPU, RAM, and the like. The control unit 31 exerts various functions by executing the program P3 stored in the storage unit 32. As its functions, the control unit 31 includes a communication establishment module 31a that establishes communication with the device adapter 20 and communication via the communication path 43, and a detection module 31b that detects interruption and restoration of communication in the communication path 43. Have.

The storage unit 32 includes a non-volatile memory such as a flash memory. In addition to the program P3, the storage unit 32 stores various data used for processing by the control unit 31.

The timer 33 is composed of, for example, a crystal oscillator or the like. The timer 33 measures the time according to the instruction of the control unit 31, and notifies the control unit 31 of the measurement result in response to the request of the control unit 31.

The input unit 34 includes a pointing device such as a keyboard and a mouse. The input unit 34 acquires, for example, the information input by the administrator and notifies the control unit 31.

The output unit 35 is composed of a liquid crystal display, a speaker, and the like. The output unit 35 displays characters and figures to the administrator and reproduces an acoustic signal according to the instructions of the control unit 31.

Each of the in-home communication unit 36 and the out-of-home communication unit 37 is composed of a communication interface and the like for communicating according to the communication protocols of the communication paths 42 and 43, respectively. Each of the in-home communication unit 36 and the out-of-home communication unit 37 outputs the data included in the packet received via each of the communication paths 42 and 43 to the control unit 31. Further, each of the in-home communication unit 36 and the out-of-home communication unit 37 generates a packet including the data output from the control unit 31 and transmits the packet via each of the communication paths 42 and 43.

Subsequently, the processes executed by each of the home device 10, the device adapter 20, and the controller 30 will be described in order with reference to FIGS. 5 to 9.

FIG. 5 shows the device processing executed by the home device 10. This device processing starts when the power of the home device 10 is turned on.

As shown in FIG. 5, the control unit 11 of the home device 10 first executes the activation sequence process (step S101). Specifically, the communication establishment module 11a confirms that the communication path 41 is in a usable state by transmitting data to the device adapter 20 and receiving data from the device adapter 20.

This activation sequence processing may include authentication of the device adapter 20. When the activation sequence processing includes authentication of the device adapter 20, the communication establishment module 11a specifies the model of the device adapter 20 or establishes communication only with the device adapter 20 having a specific function. be able to.

Next, the communication establishment module 11a determines whether or not the activation is completed (step S102). Specifically, the communication establishment module 11a determines whether or not the activation sequence processing is normally completed and communication with the device adapter 20 via the communication path 41 is established.

Next, the control unit 11 determines whether or not the communication unit 16 has received the operation instruction (step S103). Specifically, the control unit 11 determines whether or not a control command has been received via the communication path 41. This control command is, for example, a command for starting the cooling operation. When it is determined that the communication unit 16 has not received the operation instruction (step S103; No), the control unit 11 repeats the determination in step S103.

On the other hand, when it is determined that the communication unit 16 has received the operation instruction (step S103; Yes), the control unit 11 starts the operation by the output unit 15 according to the operation instruction (step S104). As a result, the home device 10 starts, for example, a cooling operation.

Next, the control unit 11 executes the communication blackout detection process (step S105). In this communication interruption detection process, the detection module 11b detects the communication interruption in each of the communication paths 41 to 43. FIG. 6 shows the details of the process executed in the communication blackout detection process.

As shown in FIG. 6, in the communication interruption detection process, the detection module 11b first determines whether or not the communication interruption of the communication path 41 to which the home device 10 is connected is detected (step S121). For example, the detection module 11b determines that the communication in the communication path 41 is interrupted when the periodic signal transmitted from the device adapter 20 in a cycle of 10 seconds has not been received in the past 30 seconds. This periodic signal may be a response from the device adapter 20 to the data transmitted from the home device 10, or may be a signal spontaneously transmitted by the device adapter 20.

Note that the interruption of communication means a state in which the communication path cannot perform its original function. For example, if communication on a communication path is interrupted, when data is transmitted from one side of the communication path, the other side cannot receive the data within a certain period of time. In this respect, the interruption of communication also includes a very narrow bandwidth and a large delay in communication.

When it is determined that the detection module 11b has not detected the communication interruption of the communication path 41 (step S121; No), the detection module 11b shifts the process to step S125. On the other hand, when it is determined that the detection module 11b has detected the communication interruption of the communication path 41 (step S121; Yes), the detection module 11b sets the first flag F1 to ON (step S122).

Next, the detection module 11b determines whether or not the timer 13 is stopped (step S123). That is, the detection module 11b determines whether or not the timer 13 has not measured the time elapsed from the specific time. When it is determined that the timer 13 is not stopped (step S123; No), the detection module 11b shifts the process to step S125.

On the other hand, when it is determined that the timer 13 is stopped (step S123; Yes), the detection module 11b starts the timer (step S124). That is, the detection module 11b causes the timer 13 to start measuring the time. As a result, the timer 13 starts measuring the length of time elapsed from the current time.

Next, the detection module 11b determines whether or not the communication unit 16 has received the interruption signal from the device adapter 20 (step S125). The interruption signal from the device adapter 20 is a signal indicating that communication in the communication path 42 has been interrupted.

When it is determined that the communication unit 16 has not received the interruption signal (step S125; No), the detection module 11b shifts the process to step S129. On the other hand, when it is determined that the communication unit 16 has received the interruption signal (step S125; Yes), the detection module 11b sets the second flag F2 to ON (step S126).

Next, the detection module 11b determines whether or not the timer 13 is stopped (step S127). When it is determined that the timer 13 is not stopped (step S127; No), the detection module 11b shifts the process to step S129. On the other hand, when it is determined that the timer 13 is stopped (step S127; Yes), the detection module 11b starts the timer 13 (step S128).

Next, the detection module 11b determines whether or not the communication unit 16 has received the interruption signal from the controller 30 (step S129). The interruption signal from the controller 30 indicates that the communication in the communication path 43 has been interrupted, and is a signal indicating the time during which the interruption continues.

When it is determined that the communication unit 16 has not received the interruption signal (step S129; No), the detection module 11b ends the communication interruption detection process. On the other hand, when it is determined that the communication unit 16 has received the interruption signal (step S129; Yes), the detection module 11b sets the third flag F3 to ON (step S130).

Next, the detection module 11b determines whether or not the time (measurement result) measured by the timer 13 is longer than the time indicated by the interruption signal determined to have been received in step S129 (step S131). .. When it is determined that the measurement result of the timer 13 is not longer than the time indicated by the interruption signal (step S131; No), the detection module 11b ends the communication interruption detection process.

On the other hand, when it is determined that the measurement result of the timer 13 is longer than the time indicated by the interruption signal (step S131; Yes), the detection module 11b starts the timer 13 with the time indicated by the interruption signal as the initial value (step S131; Yes). Step S132). As a result, the timer 13 starts measuring the length of time obtained by adding the time elapsed from the current time to the time indicated by the interruption signal. After that, the detection module 11b ends the communication blackout detection process.

Returning to FIG. 5, following the communication blackout detection process (step S105), the detection module 11b executes the communication recovery detection process (step S106). In this communication recovery detection process, the detection module 11b detects the recovery of communication in each of the communication paths 41 to 43. FIG. 7 shows the details of the process executed in the communication recovery detection process.

As shown in FIG. 7, in the communication recovery detection process, the detection module 11b first determines whether or not the first flag F1 is set to ON (step S141). When it is determined that the first flag F1 is not set to ON (step S141; No), the detection module 11b shifts the process to step S144.

On the other hand, when it is determined that the first flag F1 is set to ON (step S141; Yes), the detection module 11b determines whether or not the communication in the communication path 41 to which the home device 10 is connected is restored. Determination (step S142). For example, the detection module 11b determines that the communication on the communication path 41 has been restored when the periodic signal from the device adapter 20 has been received in the past 10 seconds.

When it is determined that the communication has not been restored (step S142; No), the detection module 11b shifts the process to step S144. On the other hand, when it is determined that the communication has been restored (step S142; Yes), the detection module 11b sets the first flag F1 to OFF (step S143).

Next, the detection module 11b determines whether or not the communication unit 16 has received the recovery signal from the device adapter 20 (step S144). The recovery signal from the device adapter 20 is a signal indicating that the communication in the communication path 42 has been restored from the interrupted state.

When it is determined that the communication unit 16 has not received the recovery signal (step S144; No), the detection module 11b shifts the process to step S146. On the other hand, when it is determined that the communication unit 16 has received the recovery signal (step S144; Yes), the detection module 11b sets the second flag F2 to OFF (step S145).

Next, the detection module 11b determines whether or not the communication unit 16 has received the recovery signal from the controller 30 (step S146). The recovery signal from the controller 30 is a signal indicating that the communication in the communication path 43 has been restored from the interrupted state.

When it is determined that the communication unit 16 has not received the recovery signal (step S146; No), the detection module 11b shifts the process to step S148. On the other hand, when it is determined that the communication unit 16 has received the recovery signal (step S146; Yes), the detection module 11b sets the third flag F3 to OFF (step S147).

Next, the detection module 11b determines whether or not all the first flag F1, the second flag F2, and the third flag F3 are set to OFF (step S148). When it is determined that the first flag F1, the second flag F2, and the third flag F3 are not all set to OFF (step S148; No), the detection module 11b ends the communication recovery detection process. That is, when it is determined that at least one of the first flag F1, the second flag F2, and the third flag F3 is set to ON, the communication recovery detection process ends.

On the other hand, when it is determined that all of the first flag F1, the second flag F2, and the third flag F3 are set to OFF (step S148; Yes), the detection module 11b stops the time measurement by the timer 13. , Reset the timer 13 (step S149). After that, the detection module 11b ends the communication recovery detection process.

Returning to FIG. 5, following the communication recovery detection process (step S106), the control unit 11 determines whether or not the time measured by the timer 13 exceeds the threshold value (step S107). This threshold is, for example, 24 hours. In addition, another time may be set in advance as a threshold value. Further, the users U1 and U2 may change the threshold value to another value by using the input unit 14.

When it is determined that the time measured by the timer 13 exceeds the threshold value (step S107; Yes), the control unit 11 sets the operating state of the home device 10 (step S108). Specifically, the state change module 11c changes the operating state of the home device 10 to a preset target state. The target state is, for example, a state of "stopping". After that, the control unit 11 repeats the processes after step S103.

On the other hand, when it is determined that the time measured by the timer 13 does not exceed the threshold value (step S107; No), the control unit 11 is based on the operation instruction determined to have been received by the communication unit 16 in step S103. It is determined whether or not the operation has ended (step S109). When it is determined that the operation has not been completed (step S109; No), the control unit 11 repeats the processes after step S105.

On the other hand, when it is determined that the operation has ended (step S109; Yes), the control unit 11 notifies the user U1 who has remotely controlled the end of the operation according to the operation instruction (step S110).

Next, the control unit 11 sets all the first flag F1, the second flag F2, and the third flag F3 to OFF (step S111). After that, the control unit 11 stops the time measurement by the timer 13 and resets the timer 13 (step S112). Then, the control unit 11 repeats the processing after step S103.

Subsequently, the adapter process executed by the device adapter 20 will be described with reference to FIG. This adapter processing starts when the power of the device adapter 20 is turned on.

As shown in FIG. 8, the control unit 21 of the device adapter 20 first executes the activation sequence process (step S201). This activation sequence processing is executed in conjunction with the activation sequence processing (step S101) by the home device 10. In the activation sequence processing of the device adapter 20, the communication establishment module 21a confirms that the communication path 41 is in a usable state. Further, the activation sequence processing may include authentication of the home device 10. By this authentication, the communication establishment module 21a can, for example, specify the model of the home device 10 connected to the device adapter 20 or establish communication only with the home device 10 having a specific function. can.

Next, the communication establishment module 21a determines whether or not the activation is completed (step S202). Specifically, the communication establishment module 21a determines whether or not the activation sequence processing is normally completed and communication with the home device 10 is established.

If it is determined that the activation is not completed (step S202; No), the control unit 21 outputs an error (step S203). After that, the control unit 21 ends the adapter processing.

On the other hand, when it is determined that the activation is completed (step S202; Yes), the communication establishment module 21a executes the connection sequence processing (step S204). Specifically, the communication establishment module 21a confirms that the communication path 42 is in a usable state by transmitting data to the controller 30 and receiving data from the controller 30.

Next, the communication establishment module 21a determines whether or not the connection is completed (step S205). Specifically, the communication establishment module 21a determines whether or not the connection sequence processing is normally completed and communication with the controller 30 is established.

When it is determined that the connection is not completed (step S205; No), the control unit 21 shifts the process to step S203. On the other hand, when it is determined that the connection is completed (step S205; Yes), the control unit 21 asks the controller 30 for the presence / absence of the time notification function (step S206). The time notification function is a function of the controller 30 and means a function of notifying the home device 10 or the device adapter 20 of the time during which communication in the communication path 43 continues to be interrupted.

Next, the control unit 21 determines the presence / absence of the time notification function based on the response from the controller 30 to the inquiry in step S206 (step S207). When it is determined that the controller 30 does not have the time notification function (step S207; No), the control unit 21 shifts the process to step S203.

On the other hand, when it is determined that the controller 30 has the time notification function (step S207; Yes), the control unit 21 starts the relay processing of the operation instruction (step S208). This relay process is a process of transmitting an operation instruction received via the communication path 42 to the home device 10 via the communication path 41. This relay process is executed in parallel with the adapter process.

Next, the detection module 21b transmits a test signal for testing the state of the communication path 42 to the controller 30 (step S209). After that, the detection module 21b determines whether or not there is a response from the controller 30 to the test signal (step S210).

When it is determined that there is no response (step S210; No), the detection module 21b transmits a interruption signal to the home device 10 (step S211). After that, the detection module 21b shifts the process to step S214.

On the other hand, when it is determined that there is a response (step S210; Yes), the detection module 21b determines whether or not this response is the first response after the transmission of the interruption signal (step S212). When the determination in step S212 is denied (step S212; No), the detection module 21b shifts the process to step S214.

On the other hand, when the determination in step S212 is affirmed (step S212; Yes), the detection module 21b transmits a recovery signal to the home device 10 (step S213).

Next, the detection module 21b waits for a certain period of time using the timer 23 (step S214). The waiting time is, for example, one minute. After that, the detection module 21b repeats the processes after step S209. As a result, the device adapter 20 determines at regular intervals whether or not communication is interrupted and restored in the communication path 42. Then, the result of the determination is notified to the home device 10.

Subsequently, the controller processing executed by the controller 30 will be described with reference to FIG. This controller processing starts when the power of the controller 30 is turned on.

As shown in FIG. 9, the control unit 31 of the controller 30 first executes the connection sequence process (step S301). This connection sequence processing is executed in conjunction with the connection sequence processing (step S201) by the device adapter 20. In the connection sequence processing of the controller 30, the communication establishment module 31a confirms that the communication paths 42 and 43 are in a usable state.

Next, the communication establishment module 31a determines whether or not the connection is completed (step S302). Specifically, the communication establishment module 31a determines whether or not the connection sequence processing is normally completed and communication via the communication paths 42 and 43 is established.

If it is determined that the connection is not completed (step S302; No), the control unit 31 outputs an error (step S303). After that, the control unit 31 ends the controller processing.

On the other hand, when it is determined that the connection is completed (step S302; Yes), the communication establishment module 31a inquires of the device adapter 20 whether or not the active detection function is provided (step S304). The active detection function means a function equivalent to the detection module 21b according to the present embodiment.

Next, the communication establishment module 31a determines whether or not the device adapter 20 has an active detection function based on the response from the device adapter 20 to the inquiry in step S304 (step S305). When it is determined that the device adapter 20 does not have the active detection function (step S305; No), the control unit 31 shifts the process to step S303.

On the other hand, when it is determined that the device adapter 20 has the active detection function (step S305; Yes), the control unit 31 starts the relay processing of the operation instruction (step S306). This relay process is a process of transmitting an operation instruction received via the communication path 43 to the home device 10 via the device adapter 20. This relay process is executed in parallel with the controller process.

Next, the detection module 31b transmits a test signal for testing the state of the communication path 43 to the server 50 (step S307). After that, the detection module 31b determines whether or not there is a response from the server 50 to the test signal (step S308).

When it is determined that there is a response (step S308; Yes), the detection module 31b determines whether or not this response is the first response after the transmission of the interrupted communication (step S309). If the determination in step S309 is denied (step S309; No), the detection module 31b shifts the process to step S314.

On the other hand, when the process of step S309 is affirmed (step S309; Yes), the detection module 31b determines that the communication in the communication path 43 has been restored, and transmits the restoration signal to the home device 10 (step S310). After that, the detection module 31b shifts the process to step S314.

When it is determined in step S308 that there is no response (step S308; No), the detection module 31b determines whether or not the timer 33 is stopped (step S311). When it is determined that the timer 33 is not stopped (step S311; No), the detection module 31b shifts the process to step S313. On the other hand, when it is determined that the timer 33 is stopped (step S311; Yes), the detection module 31b starts the timer 33 (step S312).

Next, the detection module 31b determines that the communication in the communication path 43 is interrupted, and outputs a interruption signal indicating that the communication interruption in the communication path 43 continues for the time measured by the timer 33. It is transmitted to 10 (step S313).

Next, the detection module 31b waits for a certain period of time (step S314). The waiting time is, for example, 30 minutes. After that, the detection module 31b repeats the processes after step S307. As a result, the controller 30 determines at regular intervals whether or not communication is interrupted and restored in the communication path 43. Then, the result of the determination is notified to the home device 10.

Subsequently, the communication between the home device 10, the device adapter 20, the controller 30, and the server 50 will be described with reference to FIG. The sequence diagram of FIG. 10 shows an example of communication from the establishment of communication in the communication paths 41 to 43 to the completion of remote control.

As shown in FIG. 10, the home device 10 and the device adapter 20 first execute the activation sequence S401. Specifically, the start-up sequence process by the home device 10 (step S101) and the start-up sequence process by the device adapter 20 (step S201) are executed in conjunction with each other. As a result, communication in the communication path 41 is established.

Next, the device adapter 20 and the controller 30 execute the connection sequence S402. Specifically, the connection sequence processing by the device adapter 20 (step S204) and the connection sequence processing by the controller 30 (step S301) are executed in conjunction with each other. As a result, communication on the communication path 42 is established.

Next, the device adapter 20 and the controller 30 execute the authentication sequence S403. Specifically, the device adapter 20 inquires of the controller 30 whether or not there is a time notification function (step S206). The controller 30 responds to this inquiry to the effect that it has a time notification function (step S404). Further, the controller 30 inquires of the device adapter 20 whether or not there is an active detection function (step S304). The device adapter 20 responds to this inquiry to the effect that it has an active detection function (step S405).

After that, the device adapter 20 periodically transmits a test signal to the controller 30 (step S209). When the controller 30 receives this test signal, it responds to the device adapter 20 (step S406). As a result, the device adapter 20 monitors the presence or absence of interruption of communication in the communication path 42.

Further, the controller 30 periodically transmits a test signal to the server 50 (step S307). When the server 50 receives this test signal, it responds to the controller 30 (step S407). As a result, the controller 30 monitors the presence or absence of interruption of communication in the communication path 43.

Here, when the user U1 inputs an operation instruction to the home device 10 to the operation terminal 60, the server 50 relays the transmission of the operation instruction to the home device 10 (step S411). Specifically, the server 50 transmits an operation instruction to the controller 30. After that, the controller 30 relays the transmission of the operation instruction (step S412), and the device adapter 20 also relays the transmission of the operation instruction.

Next, the home device 10 starts operation according to the operation instruction (step S104). Then, when the operation is completed, the home device 10 notifies the operation terminal 60 of the completion of the operation (step S414). Specifically, the home device 10 transmits a signal indicating that the remote control is completed to the device adapter 20. After that, the device adapter 20 notifies the controller 30 of the completion of the remote control (step S415), and the controller 30 notifies the server 50 of the completion of the remote control (step S416).

Subsequently, a case where communication in the communication paths 42 and 43 is interrupted will be described with reference to FIG. 11. In the sequence diagram of FIG. 11, the period during which communication is interrupted is indicated by the hatched area. Further, FIG. 11 shows the states of the first flag F1, the second flag F2, and the third flag F3. Box B1 in FIG. 11 indicates a period in which the first flag F1 is in the ON state, and box B2 indicates a period in which the second flag F2 is in the ON state.

In the example shown in FIG. 11, the server 50 transmits an operation instruction for causing the home device 10 to perform the cooling operation (step S421). The controller 30 transmits this operation instruction to the device adapter 20 (step S422), and the device adapter 20 transmits this operation instruction to the home device 10 (step S423). The home device 10 starts operation according to an operation instruction (step S104).

Here, when the communication in the communication path 43 is interrupted, the controller 30 detects the interruption of the communication and starts the timer 33 (step S431). The detection of this interruption corresponds to the denial of the determination in step S308 (see FIG. 9). Further, the start of the timer 33 corresponds to the start of the timer 33 in step S312.

After that, when the communication interruption in the communication path 43 continues, the controller 30 repeatedly transmits the interruption signal indicating the time during which the communication interruption continues (step S313). Then, the device adapter 20 transmits the interruption signal transmitted from the controller 30 to the home device 10 (steps S432 and S443). Since the interruption signal transmitted in step S432 is transmitted at the same time as the start of the timer 33, the interruption of communication in the communication path 43 indicates zero minutes.

Upon receiving the interruption signal from the controller 30, the home device 10 sets the second flag F2 to ON and starts the timer 13 (step S132). The setting of the second flag F2 and the start of the timer 13 are performed at the same time. As a result, the length of time measured by the timer 13 becomes equal to the length of time when the second flag F2 is ON.

Next, when the communication in the communication path 42 is interrupted, the device adapter 20 detects the interruption of the communication (step S441). The detection of this interruption corresponds to the denial of the determination in step S210 (see FIG. 8). After that, the device adapter 20 transmits a break signal indicating the break of communication in the communication path 42 to the home device 10 (step S211).

When the home device 10 receives the interruption signal from the device adapter 20, the first flag F1 is set to ON. Here, since the timer 13 has already measured the time, the control unit 11 of the home device 10 does not start or reset the timer 13 again. Therefore, the timer 13 continues to measure the time elapsed from the time when step S132 is executed.

Next, when the communication in the communication path 42 is restored, the device adapter 20 detects the restoration of this communication (step S442). The detection of this restoration corresponds to the affirmation of the determination in step S212 (see FIG. 8). After that, the device adapter 20 transmits a recovery signal to the home device 10 (step S213).

Upon receiving the recovery signal from the device adapter 20, the home device 10 sets the first flag F1 to OFF. Here, since the second flag F2 is still ON, the control unit 11 of the home device 10 does not stop or reset the timer 13. Therefore, the timer 13 continues to measure the time elapsed from the time when step S132 is executed.

Then, when the time during which the second flag F2 is ON becomes longer than the preset time T1, the home device 10 sets the operating state (step S108). That is, when the time measured by the timer 13 exceeds the time T1, the home device 10 changes the operation mode from the cooling operation to the stopped state (standby state).

As described above, the remote control system 100 according to the present embodiment changes the operating state of the home device 10 according to the time during which the communication interruption in any of the communication paths 41 to 43 continues. This makes it possible to prevent the home device 10 from continuing to operate according to the operation instruction before the interruption when the communication interruption continues. As a result, the home device 10 can be appropriately managed. Specifically, it is possible to improve the safety of the home device 10 and prevent the waste of energy by the home device 10.

Further, as shown in FIG. 5, the home device 10 has changed its operating state only when it is operated by an operation instruction via the device adapter 20 and the controller 30. Therefore, for example, when the home device 10 is directly operated by the user U2 in the house H1, the operating state of the home device 10 does not automatically change regardless of the intention of the user U2. As a result, the convenience of using the home device 10 in the house H1 is not impaired.

Further, when the time measured by the timer 13 exceeds the threshold value, the home device 10 changes the operating state to a preset target state. As a result, the home device 10 can determine whether or not to change the operating state by a simple comparison operation, and the state read from the storage unit 12 can be set as the target state as it is. As a result, the hardware resources of the home device 10 can be saved.

Further, the device adapter 20 repeatedly transmits the test signal to the controller 30 and determines whether or not there is a response from the controller 30 to the test signal, thereby detecting the interruption of communication in the communication path 42 (active detection function). As a result, the device adapter 20 can reliably detect the interruption of communication in the communication path 42.

Further, the controller 30 relays the transmission of the operation instruction only when the device adapter 20 has the active detection function. As a result, it is possible to prevent the operation instruction from being transmitted to the home device 10 via the device adapter 20 that cannot detect the interruption of communication in the communication path 42. That is, it is possible to prevent the occurrence of a situation in which the timer 13 of the home device 10 does not start even though the communication in the communication path 42 is interrupted.

Further, the controller 30 repeatedly transmitted the interruption signal indicating the time during which the communication interruption in the communication path 43 continues to the home device 10 (time notification function). Further, the home device 10 changed the operating state of the home device 10 according to the time indicated by the interruption signal. As a result, the home device 10 does not need to measure the time during which the communication interruption in the communication path 43 continues. As a result, it becomes possible to simplify the configuration of the home device 10.

Further, the device adapter 20 relays the transmission of the operation instruction only when the controller 30 has the time notification function. As a result, it is possible to prevent the operation instruction from being transmitted to the home device 10 in a situation where it is not possible to measure the time during which the communication on the communication path 43 continues to be interrupted. That is, it is possible to prevent the home device 10 from continuing to operate in accordance with the operation instruction even though the communication interruption in the communication path 43 continues for a certain period of time or longer.

In addition, the home device 10 measures the time during which communication is interrupted in at least one of the communication paths 41 to 43 using one timer 13. As a result, the configuration of the home device 10 can be reduced in size and the processing by the home device 10 can be simplified as compared with the case where the timer corresponding to each of the communication paths 41 to 43 is used.

Further, after the activation sequence by the home device 10 and the device adapter 20 was completed, the connection sequence by the device adapter 20 and the controller 30 was executed. As a result, the communication on the communication path 42 is established only when the communication on the communication path 41 is established. Therefore, immediately after the remote control system 100 is constructed, the communication on the communication path 41 is interrupted, but the communication on the communication path 42 is not established. Therefore, it becomes easy to identify the communication path where the communication is interrupted.

Embodiment 2.
Subsequently, the second embodiment will be described focusing on the differences from the first embodiment described above. For the same or equivalent configuration as that of the first embodiment, the same reference numerals are used, and the description thereof will be omitted or simplified.

The remote control system 100 according to the present embodiment is different from the one according to the first embodiment in that the controller 30 has a periodic transmission function. The periodic transmission function is a function for periodically transmitting a periodic signal to the device adapter 20. The periodic signal is transmitted, for example, in a cycle of 10 seconds. The periodic signal is used by the device adapter 20 to detect the interruption of communication in the communication path 42.

FIG. 12 shows the adapter processing according to the present embodiment. As shown in FIG. 12, when the determination in step S205 is affirmed (step S205; Yes), the communication establishment module 21a inquires the controller 30 of the presence / absence of the time notification function and the periodic transmission function (step S501).

Next, the communication establishment module 21a determines the presence / absence of both the time notification function and the periodic transmission function based on the response from the controller 30 (step S502). When it is determined that the controller 30 does not have the time notification function or the periodic transmission function (step S502; No), the control unit 21 shifts the process to step S203.

On the other hand, when it is determined that the controller 30 has both the time notification function and the periodic transmission function (step S502; Yes), the control unit 21 starts the relay processing of the operation instruction (step S208).

Next, the detection module 21b determines whether or not the communication unit 26 has received the periodic signal from the controller 30 (step S503). When it is determined that the communication unit 26 has not received the periodic signal (step S503; No), the detection module 21b determines whether or not a certain time has elapsed since the communication unit 26 last received the periodic signal. Determination (step S504). This fixed time is, for example, 30 seconds.

When it is determined that the fixed time has not elapsed (step S504; No), the detection module 21b repeats the processing after step S503. On the other hand, when it is determined that a certain time has elapsed (step S504; Yes), the detection module 21b determines that the communication in the communication path 42 has been interrupted, and transmits a interruption signal to the home device 10 (step S211). .. After that, the detection module 21b repeats the processes after step S503.

When it is determined in step S503 that the communication unit 26 has received the periodic signal (step S503; Yes), the detection module 21b determines whether or not this periodic signal is the first received after the transmission of the interruption signal. Determination (step S506). If the determination in step S506 is denied (step S506; No), the detection module 21b repeats the processes after step S503.

On the other hand, when the determination in step S506 is affirmed (step S506; Yes), the detection module 21b determines that the communication in the communication path 42 has been restored, and transmits a restoration signal to the home device 10 (step S213). After that, the detection module 21b repeats the processes after step S503.

Subsequently, the communication between the home device 10, the device adapter 20, the controller 30, and the server 50 according to the present embodiment will be described with reference to FIG. 13. The sequence diagram of FIG. 13 shows an example in which the device adapter 20 detects a communication interruption in the communication path 42.

As shown in FIG. 13, the controller 30 periodically transmits a periodic signal to the device adapter 20 (step S601). As a result, the device adapter 20 can monitor the presence or absence of interruption of communication in the communication path 42.

Then, when the reception of the periodic signal is interrupted, the device adapter 20 detects the interruption of communication in the communication path 42 (step S602). Specifically, the device adapter 20 determines that the communication is interrupted when the time T2 elapses without receiving the next periodic signal from the time when the periodic signal is last received.

As described above, the controller 30 according to the present embodiment periodically transmits a periodic signal (periodic transmission function). Then, the device adapter 20 detects the interruption of communication in the communication path 42 by determining the presence or absence of the periodic signal. As a result, the device adapter 20 can reliably detect the interruption of communication in the communication path 42.

Further, the device adapter 20 relays the transmission of the operation instruction only when the controller 30 has the periodic transmission function. This makes it possible to prevent the device adapter 20 from erroneously detecting the interruption of communication in the communication path 42 even though the communication in the communication path 42 is not interrupted.

Although the embodiments of the present invention have been described above, the present invention is not limited to the above embodiments.

For example, the method by which the controller 30 detects the interruption of communication in the communication path 43 is not limited to that according to the above embodiment. For example, when the server 50 has a periodic transmission function, the controller 30 may detect the interruption of communication in the same manner as the detection by the device adapter 20 according to the second embodiment.

Further, in the above embodiment, the operation instruction is transmitted via the server 50, but the present invention is not limited to this. For example, the operation terminal 60 may transmit an operation instruction to the controller 30 without going through the server 50. Further, it is conceivable to omit the operation terminal 60 to configure the remote control system 100. When the operation terminal 60 is omitted, the user U1 may directly input an operation instruction to the controller 30.

Further, in the above embodiment, the interruption signal transmitted from the device adapter 20 does not indicate the time during which the interruption of communication in the communication path 42 continues. However, the device adapter 20 may transmit a interruption signal indicating the time during which the communication interruption continues to the home device 10 as in the controller 30.

Further, the home device 10 may be manufactured integrally with the device adapter 20 or may have a built-in device adapter 20.

The functions of the home device 10, the device adapter 20, and the controller 30 according to the above-described embodiment can be realized by dedicated hardware or by a normal computer system.

For example, each of the programs P1 to P3 is stored in a computer-readable recording medium such as a flexible disk, a CD-ROM (Compact Disk Read-Only Memory), a DVD (Digital Versatile Disk), or an MO (Magneto-Optical disk). By distributing and installing each of the programs P1 to P3 on the computer, it is possible to configure a device that executes the above-mentioned processing.

Further, each of the programs P1 to P3 may be stored in a disk device or the like of a predetermined server device on a communication network such as the Internet, superimposed on a carrier wave, and downloaded to a computer.

Further, the above-mentioned processing can also be achieved by starting and executing while transferring each of the programs P1 to P3 via a network such as the Internet.

Further, the above-mentioned processing can also be performed by executing all or a part of each of the programs P1 to P3 on the server device and executing each of the programs P1 to P3 while the computer sends and receives information about the processing via the communication network. Can be achieved.

If the above-mentioned functions are shared by the OS (Operating System) or realized by collaboration between the OS and the application, only the parts other than the OS may be stored and distributed in the medium. You can also download it to your computer.

Further, the means for realizing the functions of the home device 10, the device adapter 20, and the controller 30 is not limited to software, and a part or all of them may be realized by dedicated hardware (circuit or the like). For example, if the communication establishment module 21a and the detection module 21b of the device adapter 20 are configured by using FPGA (Field Programmable Gate Array), ASIC (Application Specific Integrated Circuit), or the like, the power saving of the device adapter 20 can be achieved. can.

The present invention allows for various embodiments and modifications without departing from the broad spirit and scope. Further, the above-described embodiments are for explaining the present invention, and do not limit the scope of the present invention. That is, the scope of the present invention is shown not by the embodiment but by the claims. And various modifications made within the scope of the claims and within the equivalent meaning of the invention are considered to be within the scope of the present invention.

The remote control system and device management method of the present invention are suitable for remote control of devices installed in a house.

100 remote control system, 10 home equipment, 11, 21, 31 control unit, 11a, 21a, 31a communication establishment module, 11b, 21b, 31b detection module, 11c state change module, 12, 22, 32 storage unit, 13, 23 , 33 timer, 14, 34 input section, 15, 35 output section, 16 communication section, 20 equipment adapter, 26, 27 communication section, 30 controller, 36 home communication section, 37 out-of-home communication section, 41-43 communication path, 50 server, 60 operation terminal, B1, B2 box, F1 1st flag, F2 2nd flag, F3 3rd flag, H1 housing, P1-P3 program, S401 startup sequence, S402 connection sequence, S403 authentication sequence, U1, U2 User.

Claims (6)

It is a remote control system for remotely controlling home devices from a server installed outside the home.
A detection unit that detects a communication interruption in a communication path that transmits a control command indicating the content of the remote control as an operation instruction to the home device.
A state change unit that changes the state of the home device to a preset state when the detection unit detects a communication interruption in the communication path.
When the detection unit is inquired about the presence or absence of a function for detecting a communication interruption in the communication path and the detection unit responds that the detection unit has a function for detecting the communication interruption in the communication path, the operation instruction is given to the home device. The control unit that sends to
An output unit that starts the operation of the home device according to the operation instruction transmitted by the control unit, and
A remote control system equipped with. The detection unit detects the interruption of communication in the communication path based on the presence or absence of reception of a periodic signal transmitted periodically.
The remote control system according to claim 1. The detection unit detects the interruption of communication in the communication path when a certain time has elapsed since the last reception of the periodic signal.
The remote control system according to claim 2. When the detection unit detects a communication interruption in the communication path, the state change unit changes the state of the home device to the preset state after a lapse of a certain period of time.
The remote control system according to any one of claims 1 to 3. The communication path includes a first communication path for transmitting the operation instruction from the server to the communication device arranged in the house, and a second communication path for transmitting the operation instruction from the communication device to the home device. Consists of
The detection unit detects a communication interruption in at least one of the first communication path and the second communication path.
The remote control system according to any one of claims 1 to 4. It is a device management method for home devices that are remotely controlled from a server installed outside the home.
A step in which the detection unit detects a communication interruption in a communication path for transmitting a control command indicating the content of the remote control as an operation instruction to the home device.
A step of changing the state of the home device to a preset state when the detection unit detects a communication interruption in the communication path.
When the control unit inquires of the detection unit whether or not it has a function of detecting a communication interruption in the communication path and responds that the detection unit has a function of detecting a communication interruption in the communication path, the operation is performed. The step of sending the instruction to the home device and
A step in which the output unit starts the operation of the home device according to the operation instruction transmitted by the control unit, and
Equipment management methods including.

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