JP6512498B2 - Remote monitoring method, remote monitoring system, first communication device, second communication device and server device - Google Patents

Description

  The present disclosure relates to a technology for charging according to the use state of an electrical device.

  There is known a method of charging using a prepaid card as a charging system for charging according to the amount of power consumed or time of use by using an electric device such as a television, a refrigerator or an air conditioner (for example, patent documents 1).

JP, 2006-344144, A

  However, in a charging system using a prepaid card, costs such as management, production, and sales of the prepaid card occur. Also, in order to use the electric device, the user needs to purchase a prepaid card and carry the prepaid card, which is troublesome for the user. In addition, forgery of prepaid cards, copying, or the like may cause a problem that the electric device is used illegally.

  In view of the above circumstances, one non-limiting exemplary embodiment is a remote monitoring method for suppressing unauthorized use of an electrical device in a method of charging according to the user's use of the electrical device without using a prepaid card. I will provide a.

  A remote monitoring method according to an embodiment of the present disclosure includes: a first communication device connected to a server device that performs charging processing according to a power state of an electric device; and the first communication device connected to the first communication device via a wireless communication network; A remote communication system including a second communication device for monitoring a power state of the electronic device, wherein the first communication device receives power from the second communication device from the second communication device via the wireless communication network. When the on information indicating that the off state has been changed to the on state is received, the server apparatus causes the server apparatus to start billing processing for the user of the electric device, and the server apparatus causes the start process to start; (2) When it is detected that the wireless communication with the communication device is interrupted, the server device is caused to end the charging process, and the second communication device is configured to supply power to the electric device. When it is detected that the off state is changed to the on state, the on information is transmitted to the first communication device via the wireless communication network, and wireless communication with the first communication device continues. The power supply of the electric device is maintained in the on state during the interval, and the power supply of the electric device is switched from the on state to the off state when it is detected that the wireless communication with the first communication device is interrupted.

  According to the above-mentioned remote monitoring method, it becomes possible to charge according to the user's use of the electric device without using the prepaid card, and to suppress the unauthorized use of the electric device by interrupting the wireless communication. it can.

FIG. 1 is a block diagram schematically showing a system configuration of a remote monitoring system according to a first embodiment. FIG. 2 is a block diagram showing details of a system configuration of the remote monitoring system of FIG. 1; FIG. 3 is a view showing an example of the contents of a charging database in the server apparatus of FIG. 2; The graph which shows distribution of the continuation time of a radio | wireless communication interruption, and its frequency. 5 is a flowchart of user registration and charge processing by the server apparatus of FIG. 2; 5 is a flowchart of charging processing by the server apparatus of FIG. 2; FIG. 7 is a flowchart of processing relating to communication disconnection detection by the first communication device of FIG. 2; FIG. FIG. 7 is a flowchart of processing relating to communication disconnection detection by the second communication device of FIG. 2; FIG. The flowchart of the power supply control processing by the air-conditioner of FIG. FIG. 7 is a sequence diagram showing an example of system operation of the remote monitoring system of FIG. 2; The block diagram which shows the detail of the system configuration | structure of the remote monitoring system which concerns on 2nd Embodiment. FIG. 12 is a flowchart of processing relating to communication disconnection detection by the second communication device of FIG. 11; FIG. The block diagram which shows the detail of the system configuration | structure of the remote monitoring system which concerns on 3rd Embodiment. FIG. 14 is a flowchart of processing relating to communication disconnection detection by the second communication device of FIG. 13; FIG. The block diagram which shows the detail of the system configuration | structure of the remote monitoring system which concerns on 4th Embodiment. FIG. 16 is a flowchart of an air conditioner power recovery process by the server apparatus of FIG. 15; FIG. The flowchart of the power supply control processing by the air-conditioner of FIG.

Hereinafter, embodiments of the present disclosure will be described with reference to the drawings.
First Embodiment
In the remote monitoring system according to the first embodiment, the server device remotely monitors the power status of the air conditioner installed in the apartment room through the wireless communication network, and the usage fee of the air conditioner is changed according to the power status of the air conditioner. It is a charging system that performs calculation and charging processing. In the remote monitoring, it is remotely monitored whether the power state of the air conditioner is on or off.
Note that “on state” and “off state” of the power state generally mean the on / off state of the main power switch of the electric device, but the main power of the electric device is always in operation (on In the case of state), the off state of the main operation of the electric device, that is, the standby state is defined as "off state", and the on state of the main operation is defined as "on state".

As charging processing, for example, (1) charging processing for calculating and charging the usage charge of the air conditioner according to the usage time of the air conditioner, (2) charging processing for charging the usage charge according to the amount of power consumed by the air conditioner, etc. Can be mentioned.
In the first embodiment, as the charging process, a charging process of calculating and charging a usage charge according to the usage time of the air conditioner will be described as an example. When the amount of power consumed by the air conditioner is used when calculating the charge for use, for example, the charge for use per unit amount of power is determined in advance, and the amount of power consumed is notified from the air conditioner to the server device.

FIG. 1 is a block diagram schematically showing a system configuration of the remote monitoring system according to the first embodiment.
The remote monitoring system 1 illustrated in FIG. 1 includes a server device 100, first communication devices 200-1 and 200-2, second communication devices 300-1 and 300-2, and air conditioners 400-1 and 400-2. . In FIG. 1, the second communication device that performs wireless communication with the first communication device 200-2 via a wireless communication channel is omitted.

The server apparatus 100 and each of the first communication apparatuses 200-1 and 200-2 are connected by wired communication paths 50-1 and 50-2. However, the server apparatus 100 and each of the first communication apparatuses 200-1 and 200-2 may be connected by a communication path including a wireless communication path.
The first communication device 200-1 and each of the second communication devices 300-1 and 300-2 perform wireless communication via the wireless communication paths 60-1 and 60-2.

Furthermore, the second communication devices 300-1 and 300-2 are connected to the air conditioners 400-1 and 400-2, respectively, via wired communication paths 70-1 and 70-2.
Air conditioners 400-1 and 400-2 are provided in rooms 15-1 and 15-2 of apartment 10, respectively. The second communication devices 300-1 and 300-2 are installed in the rooms 15-1 and 15-2 provided with the air conditioners 400-1 and 400-2 connected by wire. Furthermore, the first communication devices 200-1 and 200-2 are installed in the corridor 20 of the apartment 10. In addition, these installation places are only an illustration.

In addition, the number of the 1st communication apparatus shown in FIG. 1, a 2nd communication apparatus, and an air-conditioner is only an illustration.
The server device 100 communicates with the first communication devices 200-1 and 200-2 via the wired communication paths 50-1 and 50-2. Further, the server device 100 remotely monitors the air conditioners 400-1 and 400-2 via the wireless communication network, calculates usage charges of the air conditioners based on the usage times of the air conditioners 400-1 and 400-2, and charges them in real time. Do. The use time of the air conditioners 400-1 and 400-2 is the time during which the power states of the air conditioners 400-1 and 400-2 are in the on state. The server device 100 is realized by, for example, a device such as a personal computer or a dedicated device. The details of the configuration and operation of the server apparatus 100 will be described later.

The first communication device 200-1 communicates with the server device 100 via the wired communication channel 50-1, and the second communication devices 300-1 and 300-1 via the wireless communication channels 60-1 and 60-2. Wireless communication with 2.
In addition, the first communication device 200-1 monitors the wireless communication in the wireless communication paths 60-1 and 60-2 and performs communication disconnection detection processing, and the communication disconnection continues when the first threshold T1 or more continues. Is notified to the server apparatus 100. Note that the communication blocking in the wireless communication paths 60-1 and 60-2 is blocking of wireless communication between the first communication device 200-1 and the second communication devices 300-1 and 300-2.

  In addition, when the first communication device 200-1 detects normal wireless communication in the wireless communication channels 60-1 and 60-2 after the communication cutoff continues for the first threshold T 1 or more, the server device 100 notifies that. Notify me. Note that normal wireless communication in the wireless communication paths 60-1 and 60-2 is, for example, normal wireless communication in the wireless communication paths 60-1 and 60-2. The first communication device 200-2 has substantially the same function as the first communication device 200-1.

The first communication devices 200-1 and 200-2 are realized by, for example, a wireless adapter for an air conditioner. The details of the configuration and operation of the first communication devices 200-1 and 200-2 and the details of the first threshold T1 will be described later.
The second communication devices 300-1 and 300-2 perform wireless communication with the first communication device 200-1 and the wireless communication paths 60-1 and 60-2, respectively, and the air conditioners 400-1 and 400-2. And communicate via the wired communication paths 70-1 and 70-2. The second communication devices 300-1 and 300-2 monitor the wireless communication in the wireless communication paths 60-1 and 60-2, respectively, and perform communication disconnection detection processing, and the communication disconnection is equal to or more than the second threshold T2. Control is performed to forcibly turn off the power supplies of the air conditioners 400-1 and 400-2 when continuing. Note that the communication blocking in the wireless communication paths 60-1 and 60-2 is blocking of wireless communication between the first communication device 200-1 and the second communication devices 300-1 and 300-2.

Also, the second communication devices 300-1 and 300-2 are in a period of time until the normal radio communication in the wireless communication channels 60-1 and 60-2 is detected after the communication cutoff continues for the second threshold T2 or more. Control is performed to forcibly turn off the power supplies of 400-1 and 400-2. Note that normal wireless communication in the wireless communication paths 60-1 and 60-2 is, for example, reception of a signal transmitted by the first communication device 200-1.
The second communication devices 300-1 and 300-2 are realized by a controller such as a Home Energy Management System (HEMS) controller, for example. The details of the configuration and operation of the second communication devices 300-1 and 300-2 and the details of the second threshold T2 will be described later.

The air conditioners 400-1 and 400-2 communicate with the second communication devices 300-1 and 300-2 via the wired communication paths 70-1 and 70-2, respectively. The air conditioners 400-1 and 400-2 output the power supply state information of the air conditioners 400-1 and 400-2 to the second communication devices 300-1 and 300-2. The power supply state information of the air conditioners 400-1 and 400-2 is information indicating that the power supply state of the air conditioner is the on state or the off state. Here, information indicating that the power state of the air conditioner is in the on state is referred to as on information, and information indicating that the power state of the air conditioner is in the off state is referred to as off information.
Furthermore, the second communication devices 300-1 and 300-2 are, for example, minimum signals corresponding to the power supply status information of the air conditioners 400-1 and 400-2 via the first communication device 200-1 as the minimum unit of the charging process. It transmits to the server apparatus 100 regularly or irregularly periodically at a time interval equal to or less than the charging time. The power state information of the air conditioners 400-1 and 400-2 is information indicating that the power state of the air conditioner is on or off (on information, off information), and an electrical device for identifying the air conditioner. Includes identification information etc. In addition, the second communication devices 300-1 and 300-2 detect the power state of the air conditioners 400-1 and 400-2, and when the power state changes, the power state information of the air conditioners 400-1 and 400-2 is output. Such a signal may be transmitted to the server device 100.

Further, for example, when there is no charge balance, the air conditioners 400-1 and 400-2 receive control of the server device 100 and forcibly turn off the power, and the second communication devices 300-1 and 300-2 are used. Force control to turn off the power. The details of the configuration and operation of the air conditioners 400-1 and 400-2 will be described later.
According to the remote monitoring system 1 described above, one server device 100 remotely and collectively executes charging processing according to the usage time of one or more air conditioners without requiring a prepaid card. Becomes possible. In addition, by using a communication channel between the first communication device and the second communication device as a wireless communication channel, wiring work between the first communication device and the second communication device becomes unnecessary, and the construction cost is significantly increased. It can be reduced. Furthermore, in the case where the communication cutoff continues in the wireless communication path between the first communication device and the second communication device for the second threshold T2 or more, or after the communication cutoff continues for the second threshold T2 or more, normal wireless communication is detected. Since the power supply of the air conditioner is forced to be turned off during the period until it becomes possible, it becomes possible to prevent unauthorized use of the air conditioner by shutting off the wireless communication path.

  FIG. 2 is a block diagram showing details of the system configuration of the remote monitoring system 1 of FIG. In FIG. 2, a user terminal 500 connectable to the server apparatus 100 is also illustrated. The first communication device 200, the second communication device 300, and the air conditioner 400 in FIG. 2 are the first communication devices 200-1 and 200-2 and the second communication devices 300-1 and 300-2 in FIG. 1, respectively. , And air conditioners 400-1 and 400-2. The wired communication path 50, the wireless communication path 60, and the wired communication path 70 in FIG. 2 are respectively the wired communication paths 50-1 and 50-2 and the wireless communication paths 60-1 and 60-2 in FIG. It corresponds to the wired communication paths 70-1 and 70-2.

First, the details of the configuration of the server apparatus 100 of FIG. 2 will be described.
The server apparatus 100 includes a communication unit 110, a charging database 120, a registration unit 130, and a monitoring unit 140.
The communication unit 110 is connected to the wired communication path 50, and transmits and receives data to and from the communication unit 210 of the first communication device 200 connected to the wired communication path 50. Further, the communication unit 110 is connected to a communication network (a communication network established by one or both of a wired communication channel and a wireless communication channel) 80, and transmits and receives data to and from a user terminal 500 connected to the communication network 80. I do.

  The charging database 120 is a database for storing charging data for each user. An example of the charging database is shown in FIG. The charging database 120 stores, for each user, a user ID, a password, identification information for identifying an air conditioner, an electricity bill, a usage time, and a charge balance. Alternatively, for example, the remaining time of the charge use time may be stored in the charge database 120 instead of the remaining charge, and the remaining time of the charge use time may be reduced according to the use time. The accounting database 120 may be provided outside the server apparatus 100.

The registration unit 130 receives user information input using the user terminal 500 when the user performs initial registration, and registers the received user information in the charging database 120. The user information is, for example, a user ID, a password, identification information of an air conditioner to be used, and the like.
In addition, the registration unit 130 receives charge fee information input using the user terminal 500 when the user charges the charge, and updates the stored contents of the charge database 120 based on the received charge fee information. The charge fee information includes a user ID, a password, and a charge fee.

The monitoring unit 140 performs charging processing according to the use of the air conditioner 400.
If the monitoring unit 140 determines that the power state of the air conditioner 400 is switched from the off state to the on state based on the power state information of the air conditioner 400 transmitted by the air conditioner 400, the charging process is started. In the charging process, the monitoring unit 140 calculates the usage time of the air conditioner 400, the electricity bill, and the charge balance, and the contents of the charging database 120 are updated. The use time of the air conditioner 400 is the time during which the power state of the air conditioner is in the on state.

In this charging process, for example, the usage charge per minimum charging time corresponding to the minimum unit of charging processing is determined, and the monitoring unit 140 controls the air conditioner per minimum charging time for each use of the minimum charging time of the air conditioner 400. Add the usage charge to the electricity bill and subtract the usage charge of the air conditioner per minimum charge time from the charge balance.
Also, when the monitoring unit 140 determines that (1) the charge balance has run out, (2) the power state of the air conditioner 400 changes from the on state to the off state based on the power state information of the air conditioner 400 transmitted by the air conditioner 400. Or (3) the accounting process is terminated when a communication interruption notification signal for notifying that the interruption of communication in the wireless communication channel 60 continued from the first communication device 200 over the first threshold T1 is received from the first communication device 200 Do.

Furthermore, when the monitoring unit 140 determines that the charge balance has run out, it outputs to the communication unit 110 a forced power off command signal for instructing the air conditioner 400 to turn off the power of the air conditioner 400 forcibly.
In some cases, a plurality of second communication devices 300 may be wirelessly connected to the first communication device 200. In this case, the monitoring unit 140 recognizes the second communication device 300 whose communication interruption has continued for the first threshold T1 or more, and stops the charging process of the air conditioner 400 connected thereto.

  An example which makes this possible is described. The first communication device 200 includes information for identifying the second communication device 300 whose communication interruption has continued for the first threshold T1 or more in the communication interruption notification signal. Also, the monitoring unit 140 may use, for example, traceroute command, and route information including information for identifying the first communication device 200 between the server device 100 and the air conditioner 400 and information for identifying the second communication device 300. Get in advance. The monitoring unit 140 specifies the air conditioner 400 connected to the second communication device 300 based on the information for identifying the second communication device 300 included in the communication disconnection notification signal using the route information acquired in advance Stop billing for usage of air conditioners.

This is merely an example, and the monitoring unit 140 recognizes the second communication device 300 whose communication interruption with the first communication device 200 continues the first threshold T1 or more, and performs charging processing of the air conditioner 400 connected thereto. Any mechanism may be used as long as it can be stopped.
Next, the configuration of the first communication device 200 of FIG. 2 will be described.
As shown in FIG. 2, the first communication device 200 includes a communication unit 210, a wireless communication unit 220, and a communication disconnection detection unit 230.

The communication unit 210 is connected to the wired communication path 50, and transmits and receives data to and from the communication unit 110 of the server apparatus 100 connected to the wired communication path 50.
The wireless communication unit 220 transmits and receives data by wireless communication with the wireless communication unit 310 of the second communication device 300 via the wireless communication path 60.
The communication disconnection detection unit 230 monitors wireless communication by the wireless communication unit 220 and performs processing of detecting communication disconnection in the wireless communication path 60 between the first communication device 200 and the second communication device 300. The communication disconnection detection unit 230 outputs a communication disconnection notification signal for notifying the server apparatus 100 to that effect to the communication unit 210, when it is determined that the communication disconnection has continued for the first threshold T1 or more. In addition, when the communication disconnection detection unit 230 determines that the communication disconnection has continued for the first threshold T1 or more and then detects normal wireless communication in the wireless communication path 60, communication recovery for notifying the server apparatus 100 accordingly. A notification signal is output to the communication unit 210.

Next, the configuration of the second communication device 300 in FIG. 2 will be described.
As shown in FIG. 2, the second communication device 300 includes a wireless communication unit 310, a communication unit 320, a communication disconnection detection unit 330, a power state monitoring unit 340, and a forced power off control unit 350.
The wireless communication unit 310 transmits / receives data by wireless communication with the wireless communication unit 220 of the first communication device 200 via the wireless communication path 60.

The communication unit 320 is connected to the wired communication path 70, and transmits and receives data to and from the communication unit 420 of the air conditioner 400 connected to the wired communication path 70.
The communication disconnection detection unit 330 monitors wireless communication by the wireless communication unit 310 and performs detection processing of communication disconnection in the wireless communication path 60 between the first communication device 200 and the second communication device 300. When the communication disconnection continues more than the second threshold T2, the communication disconnection detection unit 330 notifies the forced power off control unit 350 to that effect. Further, when the normal radio communication in the radio communication channel 60 is detected after the communication interruption continues with the second threshold T2 or more, the communication interruption detection unit 330 notifies the forcible power off control unit 350 to that effect.

The power supply state monitoring unit 340 monitors the power supply state of the air conditioner 400 and notifies the forced power supply off control unit 350 of the power supply state of the air conditioner.
For example, the power state monitoring unit 340 may detect the power state of the air conditioner 400 based on the power state information that the air conditioner 400 transmits to the server device 100. Further, the power supply state monitoring unit 340 may inquire the power supply state of the air conditioner 400 and detect the power supply state of the air conditioner 400 based on the contents of the response. Note that this detection processing is repeated periodically or irregularly, for example, at time intervals equal to or less than the minimum charging time corresponding to the minimum unit of charging processing.

  The forced power off control unit 350 determines that the power state of the air conditioner 400 is in the on state based on the notification from the power state monitoring unit 340, and the communication disconnection detection unit 330 continues the communication disconnection for the second threshold T2 or more. Receive notification that you have In this case, the forcible power off control unit 350 outputs, to the communication unit 320, a forcible power off command signal for instructing the air conditioner 400 to forcibly turn off the power of the air conditioner 400.

  Also, the forcible power off control unit 350 receives, from the power state monitoring unit 340, a period from the reception of the notification that the communication interruption has continued for the second threshold T 2 or more to the notification that the normal wireless communication has been detected. It is determined based on the notification that the power state of the air conditioner 400 has changed from the off state to the on state. In this case, the forcible power off control unit 350 outputs, to the communication unit 320, a forcible power off command signal for instructing the air conditioner 400 to forcibly turn off the power of the air conditioner 400. It should be noted that instead of outputting the forcible power off command signal, the forcible power off control unit 350 operates the user setting unit such as the remote control of the air conditioner 400 when receiving the notification that the communication cutoff continued for the second threshold T2 or more. Is output to the communication unit 320. Thereafter, when the forcible power off control unit 350 receives a notification that normal wireless communication has been detected, a signal may be output to the communication unit 320 to validate the operation of the user setting unit of the air conditioner 400. A signal for invalidating the operation of the user setting unit is transmitted to the air conditioner 400 via the communication unit 320, and the air conditioner 400 invalidates the operation of the user setting unit and takes the place of the forced power off instruction function. Further, a signal for validating the operation of the user setting unit is transmitted to the air conditioner 400 via the communication unit 320, and the air conditioner 400 validates the operation of the user setting unit.

The user interrupts the wireless communication between the second communication device 300 and the first communication device 200 by the functions of the communication disconnection detection unit 330, the power state monitoring unit 340, and the forced power off control unit 350, and the air conditioner 400 is illegal. It is possible to prevent use.
Next, the configuration of the air conditioner 400 of FIG. 2 will be described.
As shown in FIG. 2, the air conditioner 400 includes a power supply unit 410, a communication unit 420, and a power supply control unit 430.

The power supply unit 410 is a power supply of the air conditioner.
The communication unit 420 is connected to the wired communication path 70, and transmits and receives data to and from the communication unit 320 of the second communication device 300 connected to the wired communication path 70.
The power control unit 430 outputs, to the communication unit 420, a signal related to power condition information for notifying the server apparatus 100 of the power condition of the power unit 410 of the air conditioner 400.

Further, when the power control unit 430 receives a forced power off command signal for forcibly turning off the power of the air conditioner 400 transmitted by the server device 100, the power control unit 430 forcibly turns off the power of the power supply unit 410.
Also, the power control unit 430 forcibly turns off the power of the power supply unit 410 when it receives a forced power off command signal for forcibly turning off the power of the air conditioner 400 transmitted by the second communication device 300. . The forced power-off command signal indicates that, for example, when the power-off state of the air conditioner 400 is in the on-state, the communication cutoff continues more than the second threshold T2 or the normal radio communication is performed after the communication cutoff continues more than the second threshold T2. When the power of the air conditioner 400 is turned on by a remote control or the like in a period before detection, the second communication device 300 transmits the power.

Furthermore, when the user performs an operation to turn on the power using the user setting unit, the power control unit 430 turns on the power of the power supply unit 410 and the user performs an operation to turn off the power. The power of the power supply unit 410 is turned off.
The user setting unit is a device that enables the user to directly set the operating state (power on / off, etc.) of the air conditioner using a remote control such as an infrared remote control or a switch. The user setting unit may enable temperature setting. The user may set the operating state of the air conditioner via the server device 100 using the user terminal 500, but when performing via the server device 100, the setting of the air conditioner takes time, so it is set directly It is more convenient to have a user setting unit such as a remote control or a switch that can

Next, the user terminal 500 of FIG. 2 will be described.
The user terminal 500 is a terminal used by the user when performing user registration, fee charging, and the like in the charging database 120, and is connected to the communication unit 110 of the server apparatus 100 via the communication network 80. The user terminal 500 is, for example, a personal computer or a portable terminal.

The setting of the first threshold T1 and the second threshold T2 will be described below.
Unlike wired communication, wireless communication can frequently cause communication interruption even in a normal operation state. Here, the normal operation state is an operation state in which no abnormality occurs in the device related to wireless communication. The devices related to wireless communication are, for example, the first communication device 200, the second communication device 300, and the like.
As a cause of blocking of wireless communication, interference of wireless signals with other wireless systems using the same wireless band or fluctuation of wireless environment such as fading can be mentioned.
If the power of the air conditioner is forcibly turned off by regarding the communication as being interrupted whenever the wireless communication is interrupted, the frequency of the power of the air conditioner being forcibly turned off increases, and the air conditioner can be operated stably for a long time Will not be able to

In charge processing, what you want to detect as communication interruption for forcibly turning off the air conditioner is communication interruption due to fraud or communication interruption due to equipment failure, and communication that occurs frequently in normal operating conditions It is not shut off.
A wireless communication system using the same wireless band can avoid collision of packet signals by adopting a packet transmission method or a carrier sense method adopted in a wireless LAN (Local Area Network) or a wireless channel. Because it adopts a wireless communication method that can avoid interference of wireless communication, such as a change of, long-time wireless communication is unlikely to be interrupted.

Also, due to fluctuations in the radio environment such as fading, radio communication is not likely to be interrupted continuously for a long time.
Therefore, by setting the first threshold value T1 and the second threshold value T2 slightly longer, it is possible to detect a long-term communication interruption that can not occur in the normal operation state, and also cause frequent communication interruptions in the normal operation state. Power can not be forced off frequently.
Next, a method of measuring a typical value of continuous duration time of communication interruption of wireless communication in a normal operation state and its definition will be described.
For example, it is assumed that the number of packets of wireless communication transmitted in the normal operation state is Ns, the time for transmitting all the packets is Ts, the packet error rate at that time is Ps, and the packet length is T1. In the normal operation state, the packet error rate is at most, for example, 0.1% to 1%. At this time, the number of error packets (= Ne) is Ne = Ns × Ps, and when error packets are not continuously generated, the duration of error (= Tx) is Tx = Ts / Ns. On the other hand, when all the error packets occur continuously, the error duration time is Tx = Ne × Tl = Ns · Ps · Tl. Therefore, the typical value of the continuous duration of the communication interruption of the wireless communication in the normal operation state can be estimated to be a value between approximately Ts / Ns seconds and Ns · Ps · Tl seconds. Although this value varies depending on the communication environment, in the case of a standard such as W-LAN (IEEE 802.11) or ZigBee (IEEE 802.15.4) in a normal wireless environment, about 1 msec to 100 msec is a typical value. is there.
Here, if the first threshold T1 and the second threshold T2 are set sufficiently longer than this typical value, it is avoided that the power supply of the air conditioner is forced to be turned off frequently due to the communication interruption frequently occurring in the normal operation state. it can.
Note that the above is an example of a typical value of the continuous duration time of communication interruption of wireless communication in the normal operation state, or an example of a method of measuring the time equivalent thereto, and another method may be used. Further, the typical value of the continuous interruption duration can be roughly estimated if the wireless communication standard is determined, and is not unique to the remote monitoring system or the like. For example, the typical value of the continuous duration of the communication interruption of the wireless communication in the normal operation state may be an average value of the continuous duration of the communication interruption.

  FIG. 4 shows an example of measurement results of the continuous duration of the communication interruption of the wireless communication and the frequency distribution thereof. From this graph, it is assumed that the average value of the continuous duration of the communication interruption of the wireless communication is about 10 milliseconds. In addition, since the relationship between the continuous continuation time of communication interruption | blocking of wireless communication and the distribution of the frequency changes with each installation places of the communication apparatus which performs wireless communication, it measures in the place which installs them, for example.

  Here, if the first threshold T1 and the second threshold T2 are set to be sufficiently long compared to 10 ms of this average value, the communication interruption which forces the power supply of the air conditioner to be turned off frequently occurs in the normal operation state. As a result, the air conditioner can be prevented from being forced to turn off frequently. The first threshold T1 and the second threshold T2 may be the same value or may be different. The second threshold T2 may be a value equal to or less than the first threshold T1. In this case, since the power supply of the air conditioner is turned off earlier than when the charging process is stopped at the time of communication interruption, it is possible to prevent the device from being used for free.

However, if the setting time of the first threshold T1 and the second threshold T2 is too long, the following problem occurs.
Until the second threshold T2 elapses after the first communication interruption is detected, it is not possible to judge whether the communication interruption may occur in the normal operation state or the communication interruption due to some error such as fraud. That is, the charging process can not be performed with an accuracy equal to or less than the first threshold T1 and the second threshold T2.

Assuming that the minimum charging time corresponding to the minimum unit of charging processing is, for example, one minute, each processing time of the system is about one minute or less in order to be able to charge in real time with an accuracy of less than one minute in the charging processing.
The shorter the time to characterize the real-time nature of the system, the better. It is desirable that the delay time be at least equal to or less than the allowable delay time allowed for the system.

Therefore, by making the first threshold T1 and the second threshold T2 equal to or less than the allowable delay time, it is possible to satisfy the delay performance suitable for the system.
Further, in the case of the charging process, as long as it is shorter than the minimum charging time, there may be some delay in the processing time. That is, the first threshold T1 and the second threshold T2 may be made shorter than the minimum charging time.

The operation of each device (server device 100, first communication device 200, second communication device 300, air conditioner 400) of the remote monitoring system 1 of FIG. 2 will be described below using the drawings.
First, user registration and fee charging processing by the server apparatus 100 of FIG. 2 will be described with reference to FIG. However, in order to simplify the description of the user registration and the fee charge processing, FIG. 5 is intended for one user.

  In the server device 100, the registration unit 130 determines whether user information (user ID, password, electrical device identification information of an air conditioner to be used) has been received (step S101). The registration unit 130 performs the process of step S101 until the user information is received (S101: NO). On the other hand, when the registration unit 130 receives user information (S101: YES), the registration unit 130 registers the received user information in the charging database 120 (step S102). Note that the user can also charge a charge at the time of user registration by including the charge fee in the user information.

  The registration unit 130 determines whether charge charge information (user ID, password, charge charge) has been received (step S103). The registration unit 130 performs the process of step S103 until the charge fee information is received (S103: NO). On the other hand, when the registration unit 130 receives the charge charge information (S103: YES), after performing password authentication and the like, the charge charge is added to the charge database 120 based on the charge charge information (step S104).

Next, charging processing by the server apparatus 100 of FIG. 2 will be described using FIG.
FIG. 6 is a flowchart showing charging processing by the server apparatus 100 of FIG. However, in order to simplify the explanation of the charging process, FIG. 6 is intended for one user.
In the server device 100, the monitoring unit 140 determines whether the power state of the air conditioner 400 changes from the off state to the on state based on the power state information transmitted from the air conditioner 400 (step S131). The monitoring unit 140 performs the process of step S131 until it is determined that the power state of the air conditioner 400 changes from the off state to the on state (S131: NO).

  On the other hand, when the monitoring unit 140 determines that the power supply state of the air conditioner 400 is switched from the off state to the on state (S131: YES), it determines whether the user of the air conditioner 400 has a charge balance by referring to the charging database 120. (Step S132). Here, "there is a charge balance" means that there is a charge balance equal to or higher than the usage charge of the air conditioner per minimum charge time corresponding to the minimum unit of charge processing. If it is determined that there is no charge balance (S132: NO), the monitoring unit 140 transmits a forced power off command signal for forcibly turning off the power of the air conditioner 400 to the air conditioner 400 (step S133). The forced power off command signal is received by the air conditioner 400 via the wired communication path 50, the first communication device 200, the wireless communication path 60, the second communication device 300, and the wired communication path 70. The power control unit 430 of the air conditioner 400 receives the forced power off command signal to forcibly turn off the power of the power unit 410. Further, the monitoring unit 140 transmits a notification signal for notifying the user terminal 500 that there is no charge balance (step S134). The user terminal 500 receives this notification signal and displays, for example, that there is no charge balance.

If it is determined that there is a charge balance (S132: YES), the monitoring unit 140 starts charging processing (step S135). The charging process is, for example, measurement of use time, calculation of electricity cost from use time, charge balance reduction, and the like. In the charging process, a process of reducing the usage charge of the air conditioner per minimum charging time from the charge balance is performed every minimum charging time corresponding to the minimum unit of the charging process.
In the charging process, the monitoring unit 140 refers to the charging database 120 and determines whether the user of the air conditioner 400 has a charge balance (step S136). If it is determined that there is no charge balance (S136: NO), the monitoring unit 140 ends the charging process (step S137), and the process of step S133 is performed. On the other hand, if it is determined that there is a charge balance (S136: YES), the process of step S138 is performed.

  Whether the monitoring unit 140 has received from the first communication device 200 a communication disconnection notification signal for notifying that the communication disconnection between the first communication device 200 and the second communication device 300 has continued for the first threshold T1 or more It determines (step S138). If it is determined that the communication disconnection notification signal has been received (S138: YES), the monitoring unit 140 ends the charging process (step S140), and notifies the user terminal 500 of the charging process result such as the charge balance. (Step S141). The user terminal 500 receives this notification and displays the charge processing result such as the charge balance.

  If it is determined that the communication cutoff notification signal has not been received (S138: NO), whether the power state of the air conditioner 400 has changed from the on state to the off state based on the power state information transmitted from the air conditioner 400 It determines (step S139). If it is determined that the power state of the air conditioner 400 does not become the off information from the on state (S139: NO), the process of step S136 is performed. On the other hand, when it is determined that the power state of the air conditioner 400 has changed from the on state to the off information (139: YES), the process of step S140 is performed.

Next, processing regarding detection of communication interruption by the first communication device 200 of FIG. 2 will be described using FIG. 7.
FIG. 7 is a flowchart showing a process related to communication interruption detection by the first communication device 200 of FIG.
In the first communication device 200, the communication disconnection detection unit 230 monitors wireless communication in the wireless communication path 60 and performs communication disconnection detection processing (step S201). Note that the detection of the presence or absence of communication interruption is repeatedly performed periodically or irregularly, for example, at a time interval shorter than the first threshold T1. The communication disconnection detection unit 230 performs the process of step S201 until the communication disconnection is detected (S201: NO). On the other hand, when the communication disconnection detection unit 230 detects the communication disconnection (S201: YES), the communication disconnection detection unit 230 records the time (t1) at which the communication disconnection is detected as the disconnection start time (step S202).

  The communication disconnection detection unit 230 determines whether communication disconnection continued at the time t by the first threshold T1 or more (t-t1 ≧ T1?) (Step S203). When it is not determined that the communication disconnection continues at the first threshold T1 or more at time t (S203: NO), the communication disconnection detection unit 230 determines that the wireless communication channel 60 is normal after the disconnection start time (t1). A communication detection process is performed (step S204). Note that the detection of the presence or absence of normal wireless communication is repeatedly performed periodically or irregularly, for example, at time intervals shorter than the first threshold T1. If normal wireless communication is not detected (S204: NO), the process of step S203 is performed. On the other hand, when normal wireless communication is detected (S204: YES), the process of step S201 is performed.

  If it is determined at time t that communication interruption continued for the first threshold T1 or more (S203: YES), the communication interruption detection unit 230 intercepts communication to notify that communication interruption continued for the first threshold T1 or more. A notification signal is transmitted to the server apparatus 100 (step S205). The server apparatus 100 receives the communication disconnection notification signal (YES in step S138 in FIG. 6), and concludes that the power state of the air conditioner 400 is changed from the on state to the off state, and ends the charging process (FIG. 6). Step S140).

  The communication interruption detection unit 230 detects normal wireless communication in the wireless communication path 60 (step S206). The communication disconnection detection unit 230 performs the process of step S206 until a normal wireless communication is detected (S206: NO). On the other hand, when normal wireless communication is detected (S206: YES), the communication disconnection detection unit 230 performs communication for notifying that normal wireless communication is detected after the communication disconnection continues for the first threshold or more. A cutoff end notification signal is transmitted to the server device 100 (step S207).

Next, processing relating to communication interruption detection by the second communication device 300 in FIG. 2 will be described using FIG.
FIG. 8 is a flowchart showing a process related to communication interruption detection by the second communication device 300 of FIG.
In the second communication device 300, the communication disconnection detection unit 330 monitors wireless communication in the wireless communication channel 60 and performs communication disconnection detection processing (step S301). Note that the detection of the presence or absence of communication interruption is repeatedly performed periodically or irregularly, for example, at a time interval shorter than the second threshold T2. The communication disconnection detection unit 330 performs the process of step S301 until the communication disconnection is detected (S301: NO). On the other hand, when the communication disconnection detection unit 330 detects the communication disconnection (S301: YES), the communication disconnection detection unit 330 records the time (t2) at which the communication disconnection is detected as the disconnection start time (step S302).

  The communication disconnection detection unit 330 determines whether communication disconnection continued at the time t by the second threshold T2 or more (t-t2 ≧ T2?) (Step S303). If it is not determined at time t that the communication interruption has continued for the second threshold T2 or more (S303: NO), the communication interruption detection unit 330 determines that the wireless communication path 60 is normal after the interruption start time (t2). A communication detection process is performed (step S304). Note that the detection of the presence or absence of normal wireless communication is repeatedly performed periodically or irregularly, for example, at time intervals shorter than the second threshold T2. If normal wireless communication is not detected (S304: NO), the process of step S303 is performed. On the other hand, when normal wireless communication is detected (S304: YES), the process of step S301 is performed.

  If it is determined at time t that the communication interruption has continued for the second threshold T2 or more (S303: YES), the forced power off control unit 350 causes the power state monitoring unit 340 to monitor the power state of the air conditioner 400 based on the monitoring result. It is determined whether the power supply state of the air conditioner 400 is in the on state (step S305). If it is determined that the power supply state of the air conditioner 400 is not in the on state (S305: NO), the process of step S307 is performed. On the other hand, if it is determined that the power state of air conditioner 400 is in the on state (S305: YES), forced power off control unit 350 generates a forced power off command signal for forcibly turning off the power of air conditioner 400. It transmits to the air conditioner 400 (step S306). The air conditioner 400 receives this forced power off command signal via the wired communication path 70, and the power control unit 430 of the air conditioner 400 forcibly turns off the power of the power supply unit 410.

As described above, when the power supply state of the air conditioner 400 is in the on state and the communication cutoff continues for the second threshold T2 or more, the power supply of the air conditioner 400 is forcibly turned off. This makes it possible to prevent unauthorized use of the air conditioner 400 that abuses the communication interruption.
The forcible power off control unit 350 determines whether the power state of the air conditioner 400 changes from the off state to the on state during the continuation of the communication disconnection based on the monitoring result of the power state of the air conditioner 400 by the power state monitoring unit 340 (step S307) . The determination as to whether the air conditioner 400 has been turned on is periodically or irregularly repeated at a time interval shorter than the minimum charging time corresponding to the minimum unit of the charging process, for example. If it is not determined that the power state of the air conditioner 400 has been switched from the off state to the on state (S307: NO), the process of step S309 is performed. On the other hand, if it is determined that the power state of the air conditioner 400 is changed from the off state to the on state (S307: YES), the forced power off control unit 350 forces off the power for forcibly turning off the power of the air conditioner 400. A command signal is sent to the air conditioner 400 (step S308). The air conditioner 400 receives this forced power off command signal via the wired communication path 70, and the power control unit 430 of the air conditioner 400 forcibly turns off the power of the power supply unit 410.

The communication disconnection detection unit 330 performs a detection process of normal wireless communication in the wireless communication channel 60 (step S309). If normal wireless communication is not detected (S309: NO), the process of step S307 is performed. On the other hand, when normal wireless communication is detected (S309: YES), the process of step S301 is performed.
As described above, during the period from when the communication interruption continues for the second threshold T 2 or more to when the normal wireless communication is detected, the user can turn on the power of the air conditioner using a remote control or the like. Power is forced off. This makes it possible to prevent unauthorized use of the air conditioner 400 that abuses the communication interruption.

Next, power control processing by the air conditioner 400 of FIG. 2 will be described with reference to FIG.
FIG. 9 is a flowchart showing power control processing by the air conditioner 400 of FIG.
In the air conditioner 400, the power control unit 430 determines whether the user has performed an operation to turn on the air conditioner 400 (step S401). The power control unit 430 performs the process of step S401 until it is determined that the user has performed an operation to turn on the air conditioner 400 (S401: NO). On the other hand, if the power control unit 430 determines that the user has performed an operation to turn on the air conditioner 400 (S401: YES), the power control unit 430 turns on the power of the power supply unit 410 (step S402). Then, the power control unit 430 transmits a signal regarding power state information for notifying the server device 100 that the power state of the air conditioner 400 is in the on state (step S403).

  The power control unit 430 determines whether a forced power off command signal for forcibly turning off the power of the air conditioner 400 has been received from the server apparatus 100 or the second communication apparatus 300 (step S404). If it is determined that the forcible power off command signal has not been received (S404: NO), the process of step S406 is performed. On the other hand, when it is determined that the forcible power off command signal has been received (S404: YES), the power control unit 430 forcibly turns off the power of the power supply unit 410 (step S405). Then, the power control unit 430 transmits a signal regarding power state information for notifying the server device 100 that the power state of the air conditioner 400 is in the off state (step S406). Hereby, when there is no charge balance, the server apparatus 100 can know that the power supply of the air conditioner is forcibly turned off.

  The power control unit 430 determines whether the user has performed an operation to turn off the air conditioner 400 (step S407). If it is determined that the user has not performed an operation to turn off the air conditioner 400 (S407: NO), the process of step S404 is performed. If it is determined that the user has performed an operation to turn off the air conditioner 400 (S407: YES), the power control unit 430 turns off the power of the power supply unit 410 (step S408). Then, the power control unit 430 transmits a signal regarding power state information for notifying the server apparatus 100 that the power state of the air conditioner 400 is in the off state (step S409).

Hereinafter, an example of the system operation of the remote monitoring system 1 of FIG. 2 will be described with reference to FIG.
FIG. 10 is a sequence diagram showing an example of the system operation of the remote monitoring system 1 of FIG. However, FIG. 10 is a sequence diagram when communication interruption occurs in the wireless communication path between the first communication device 200 and the second communication device 300 when the power of the air conditioner is turned on.

  The user performs a charge input operation for inputting a user ID, a password, and a charge fee using the user terminal 500 (step S11), and the user terminal 500 transmits charge fee information to the server apparatus 100 (step S12). The server apparatus 100 receives the charge fee information, and charges the charge database 120 based on the charge fee information (step S13). The charge fee information includes, for example, a user ID, a password, a charge fee, and the like.

  The power of the air conditioner 400 is turned on by the user operation (step S14), and the air conditioner 400 transmits to the server device 100 a signal regarding power condition information for notifying the server device 100 that the power condition of the air conditioner is on. (Step S15). This signal is transmitted via the wired communication path 70, the second communication device 300 (communication unit 320, wireless communication unit 310), the wireless communication path 60, the first communication device 200 (wireless communication unit 220, communication unit 210), and the wired communication path 50. The server device 100 is reached via the link. The server device 100 recognizes that the power of the air conditioner 400 is turned on, and starts the charging process when there is a charge balance (step S16).

The second communication device 300 detects the communication cutoff continued for the second threshold T2 or more (step S17), and instructs the air conditioner 400 to forcibly turn off the power (step S18). The air conditioner 400 forcibly turns off the power according to this command (step S19).
The first communication device 200 detects communication disconnection continued for the first threshold T1 or more (step S20), and notifies the server device 100 that communication disconnection has been detected (step S21). The server device 100 receives the notification that the communication disconnection has been detected, and ends the charging process (step S22). The server apparatus 100 notifies the user terminal 500 of the charging process result (step S23), and the user terminal 500 displays the charging process result (step S24).

Second Embodiment
Hereinafter, the remote monitoring system according to the second embodiment will be described with reference to the drawings. In the second embodiment, components and processing steps that perform substantially the same processing as in the first embodiment are denoted by the same reference numerals, and descriptions thereof will be omitted since they can be applied.

The second embodiment is a method of forcibly turning off the power supply of the air conditioner 400 during a period from when the second communication device detects communication interruption continuing for the second threshold T 2 or more to when it detects normal wireless communication. As a second method, a method different from the first embodiment is used.
This other method is forced to turn off the power of the air conditioner 400 during a period from when the second communication device 300 detects communication interruption continuing for the second threshold or more to when it detects normal wireless communication. The power off command signal is sent to the air conditioner 400 periodically or periodically.

FIG. 11 is a block diagram showing details of the system configuration of the remote monitoring system 1A according to the second embodiment.
The remote monitoring system 1A is different from the remote monitoring system 1 of FIG. 2 in that the second communication device 300 does not have the power state monitoring unit 340, and instead of the forced power off control unit 350, a forced power off control unit 350A. It has a system configuration replaced with the second communication device 300A.

  The forcible power off control unit 350A instructs the air conditioner 400 to forcibly turn off the power supply of the air conditioner 400 when notified by the communication disconnection detection unit 330 that the communication disconnection has continued for the second threshold T2 or more. A forced power off command signal is output to the communication unit 320. In addition, the forced power off control unit 350A receives a notification from the communication disconnection detection unit 330 that the communication disconnection has continued for the second threshold T2 or more, and then receives a notification from the communication disconnection detection unit 330 until it receives a notification that normal wireless communication is detected. A forced power off instruction signal for instructing the air conditioner 400 to forcibly turn off the power of 400 is output to the communication unit 320. For example, in the above period, the forced power off control unit 350 repeatedly or periodically outputs the forced power off command signal to the communication unit 320 periodically or irregularly at a time interval shorter than the minimum charging time corresponding to the minimum unit of charging processing. Do.

In the first embodiment, since the power state monitoring unit 340 is provided, the forced power off command signal is transmitted only when the power of the air conditioner 400 is turned on. On the other hand, in the second embodiment, since the power state monitoring unit 340 is not provided, the power of the air conditioner 400 transmits a forced power off command signal regardless of whether the power is on or off.
FIG. 12 is a flowchart showing a process related to communication interruption detection by the second communication device 300A of FIG.

  In the second communication device 300A, substantially the same processing as in steps S301 to S304 described with reference to FIG. 8 is performed. Then, if step S303 is YES, the forced power off control unit 350A transmits a forced power off command signal for forcibly turning off the power of the air conditioner 400 to the air conditioner 400 (step S306). In response to the forced power off command signal, the power control unit 430 of the air conditioner 400 forcibly turns off the power of the power supply unit 410 when the power state is in the on state. This makes it possible to prevent unauthorized use of the air conditioner 400 that abuses the communication interruption.

The forced power-off control unit 350A repeatedly transmits a forced power-off command signal for forcibly turning off the power of the air conditioner 400 to the air conditioner 400 (step S331).
The communication interruption detection unit 330 detects normal wireless communication in the wireless communication channel 60 (step S332). If normal wireless communication is not detected (S332: NO), the process of step S331 is performed. On the other hand, if normal wireless communication is detected (S332: YES), the process of step S301 is performed.

As described above, during the period from when the communication interruption continues for the second threshold T 2 or more to when the normal wireless communication is detected, the user can turn on the power of the air conditioner using a remote control or the like. Power is forced off. This makes it possible to prevent unauthorized use of the air conditioner 400 that abuses the communication interruption.
The method described in the second embodiment does not require the power state monitoring unit 340 for monitoring the power state of the air conditioner 400.

Third Embodiment
The remote monitoring system according to the third embodiment will be described below with reference to the drawings. In the third embodiment, components and processing steps that perform substantially the same processing as in the first embodiment are given the same reference numerals, and descriptions thereof will be omitted since they can be applied.

The remote monitoring system according to the third embodiment notifies the user to that effect when the power supply of the air conditioner is forcibly turned off.
FIG. 13 is a block diagram showing details of the configuration of the remote monitoring system according to the third embodiment.
As shown in FIG. 13, the remote monitoring system 1B includes a second communication device 300B in which a forced power off notification unit 360 is added to the second communication device 300 of the first embodiment. The forced power-off control unit 350 notifies the forced power-off notifying unit 360 of that effect each time the air-conditioner 400 is instructed to forcibly turn off the power.

The forced power off notification unit 360 controls to forcibly turn off the power of the air conditioner 400 every time it receives a notification from the forced power off control unit 350 that it instructs the air conditioner 400 to forcibly turn off the power. Inform the user that it has done. As a method of informing the user, for example, lighting or blinking of an LED, output of a buzzer sound, and the like can be given.
FIG. 14 is a flowchart showing a process related to communication interruption detection by the second communication device 300B of FIG.

  In the second communication device 300B, substantially the same processing as in steps S301 to S306 described with reference to FIG. 8 is performed. Subsequent to the process of step S306, the forcible power off notification unit 360 performs a process for notifying the user of the forcible turn off of the power of the air conditioner 400 (step S306B). This allows the user to know that the power of the air conditioner 400 has been forcibly turned off.

  In the second communication device 300B, substantially the same processing as in steps S307 to S308 described with reference to FIG. 8 is performed. Following the process of step S308, the forcible power off notification unit 360 performs a process for notifying the user of the forcible turn off of the power of the air conditioner 400 (step S308 B). This allows the user to know that the power of the air conditioner 400 has been forcibly turned off.

In the second communication device 300B, substantially the same processing as step S309 described using FIG. 8 is performed.
When the power of the air conditioner 400 is forcibly turned off, the user may be informed that the cause of the forced off of the air conditioner 400 is due to the communication interruption.
Also, a function of notifying the user of forced power off may be added to the second embodiment. In this case, for example, when it is determined that the communication cutoff has continued for the second threshold T2 or more, a period from when it is determined that the communication cutoff has continued for the second threshold T2 or more to when a normal wireless communication is detected The off notification unit 360 keeps notifying the user of the forced off of the power supply of the air conditioner. As a method of informing the user of the forcible turning off of the power supply of the air conditioner, for example, it is possible to keep on lighting or blinking of the LED.

Fourth Embodiment
The remote monitoring system according to the fourth embodiment will be described below with reference to the drawings. In the fourth embodiment, components and processing steps that perform substantially the same processing as in the first embodiment are given the same reference numerals, and descriptions thereof will be omitted since they can be applied.

In the remote monitoring system according to the fourth embodiment, when normal wireless communication is detected after the interruption of communication continues between the first communication device 200 and the second communication device 300 after the first threshold T1 or more, The power supply state of the air conditioner is brought into a state before detection of communication interruption in which the first threshold T1 or more continues.
FIG. 15 is a block diagram showing the details of the configuration of the remote monitoring system according to the fourth embodiment.

The remote monitoring system 1C has a system configuration in which the server device 100 is replaced with the server device 100C and the air conditioner 400 is replaced with the air conditioner 400C in the remote monitoring system 1 of the first embodiment, as shown in FIG. There is.
The server apparatus 100C includes a monitoring unit 140C obtained by adding the function of the power state recovery unit 150 to the monitoring unit 140 according to the first embodiment.

  The power supply state recovery unit 150 holds the power supply state of the air conditioner 400C before detection of communication interruption continuing for the first threshold T1 or more is detected. The power supply state recovery unit 150 detects a normal radio communication after the detection of communication interruption continuing for the first threshold T1 or more, and the power supply state of the air conditioner 400C is in the ON state before the communication interruption detection. And outputs a power on command signal to the communication unit 110 to turn on.

The air conditioner 400C has a configuration in which the power control unit 430 of the first embodiment is replaced with a power control unit 430C.
In addition to the processing of the power control unit 430 of the first embodiment, the power control unit 430C turns on the power of the power supply unit 410 when the power on command signal transmitted by the server apparatus 100C is received.

FIG. 16 is a flowchart showing the power supply recovery process of the air conditioner by the server apparatus 100C of FIG. Although the power supply state of the air conditioner 400C is described as being held by the power supply state flag, one other than the power supply state flag may be used.
In the server device 100C, the monitoring unit 140C determines whether the power state of the air conditioner 400C is the off state or the on state based on the power state information transmitted from the air conditioner 400C (step S151). If it is determined that the power state of the air conditioner 400C is in the on state (S151: YES), the power state recovery unit 150 turns on the power state flag (step S152). If it is determined that the power state of the air conditioner 400C is in the off state (S151: NO), the power state recovery unit 150 turns off the power state flag (step S153).

  Whether the monitoring unit 140 has received from the first communication device 200 a communication disconnection notification signal for notifying that the communication disconnection between the first communication device 200 and the second communication device 300 has continued for the first threshold T1 or more It determines (step S154). If it is determined that the communication disconnection notification signal has been received (S154: YES), the process of step S155 is performed. If it is determined that the communication disconnection notification signal has not been received (S154: NO), the process of step S151 is performed.

  The monitoring unit 140C determines whether a communication disconnection end notification signal has been received from the first communication device 200 for notifying that normal wireless communication has been detected after the communication disconnection has continued for the first threshold or more (step S155). . If it is determined that the communication disconnection end notification signal has not been received (S155: NO), the process of step S155 is performed. If it is determined that the communication disconnection end notification signal has been received (S155: YES), the monitoring unit 140C determines whether the power state flag is on (step S156). If it is determined that the power state flag is on (S156: YES), power state recovery unit 150 generates a forced power off cancellation instruction signal for canceling forced power off of air conditioner 400C and the power of air conditioner 400C. A power on command signal to turn on is sent to the second communication device 300. The second communication device 300 cancels the forced power off function, and transmits a power on command signal to the air conditioner 400C (step S157). The power on command signal reaches the air conditioner 400C via the wired communication path 50, the first communication device 200, the wireless communication path 60, the second communication device 300, and the wired communication path 70. The power control unit 430C of the air conditioner 400C turns on the power of the power supply unit 410. On the other hand, when it is determined that the power state flag is off (S156: NO), the power state recovery unit 150 transmits a forced power off cancellation instruction signal to the second communication device 300, and the second communication device 300. Releases the forced power off function. (Step S158).

  In the first embodiment and the second embodiment, the forced power-off cancellation command detects normal wireless communication after detecting that the second communication device has continued the second threshold T2 or more. It is an instruction to release the forced power-off function of forcibly turning off the power of the air conditioner 400 in the period up to. The second communication device 300 and the air conditioner 400C can be restored to the state before the communication interruption by the forced power off cancellation instruction signal.

FIG. 17 is a flowchart showing power control processing by the air conditioner 400C of FIG.
In the air conditioner 400C, substantially the same process as step S301 described with reference to FIG. 9 is performed. If NO in step S401, the power control unit 430C determines whether a power on command signal for turning on the power of the air conditioner 400 has been received from the server apparatus 100C (step S401C). If it is determined that the power on command signal has been received (S401C: YES), the process of step S402 is performed. On the other hand, when it is determined that the power on command signal has not been received (S401C: NO), the process of step S401 is performed.

In the air conditioner 400C, substantially the same processing as that in steps S402 to S409 described with reference to FIG. 9 is performed.
In the fourth embodiment, when normal radio communication is detected when the power of the air conditioner 400C is forcibly turned off due to communication interruption, the power of the air conditioner 400C is automatically controlled by remote control by the server apparatus 100C. Turned on. For this reason, the user does not have to perform the power-on operation of the air conditioner 400 each time.

Note that instead of providing the power state recovery unit 150 in the server device, a function equivalent to that of the power state recovery unit 150 may be added to the first communication device 200.
Also, instead of providing the power state recovery unit 150 in the server device 100C, normal wireless communication is detected after interruption of communication between the first communication device 200 and the second communication device 300 continues for the second threshold T2 or more. In such a case, a function may be added to the second communication apparatus 300 to make the power supply state of the air conditioner a state before detection of communication interruption that continues the second threshold T2 or more.

Fifth Embodiment
Hereinafter, the remote monitoring system according to the fifth embodiment will be described with reference to the drawings.
In the fifth embodiment, a method will be described in which each of the first communication device 200 and the second communication device 300 detects the communication interruption in the wireless communication path between the first communication device and the second communication device.

  It is assumed that the first communication interruption detection signal is transmitted from the first communication device 200 to the second communication device 300 periodically or irregularly. When the second communication device 300 does not receive the first communication disconnection detection signal within a predetermined time, the second communication device 300 can detect the communication disconnection by determining that the communication is disconnected. Transmission of the first communication interruption detection signal is performed at least once within a predetermined time. The predetermined time is a time shorter than the second threshold T2.

  Further, it is assumed that the second communication disconnection detection signal is transmitted from the second communication device 300 to the first communication device 200 periodically or irregularly. When the first communication device 200 does not receive the second communication disconnection detection signal within a predetermined time, the first communication device 200 can detect the communication disconnection by determining that the communication is disconnected. The transmission of the second communication interruption detection signal is performed at least once within a predetermined time. The predetermined time is a time shorter than the first threshold T1.

Here, a signal newly defined to detect communication interruption may be used as the first communication interruption detection signal and the second communication interruption detection signal, or an existing signal may be used.
Here, a detection method of communication interruption will be described by taking a token method as an example.
In the token method, the server device transmits a token time "right" for permitting use of the communication channel for a short fixed time from the first communication device to the second communication device, and the use of the communication channel for the token time is completed. The transmission of the “right” of the new token time to the second transmitter is repeated.

The second communication device requests the first communication device to "right" for token time, and the first communication device transmits the token time "right" to the second communication device. This transmission and reception is performed each time the second communication device runs out of token time.
The first communication apparatus determines that the communication is interrupted when the request for the "right" of the next token time is not received until the predetermined time elapses after the request for the "right" of the token time last time.

When the second communication device does not receive the next token time “right” after receiving the token time “right” last time or until the predetermined time elapses after the received token time is used up, to decide.
<< supplement (the 1) >>
The present disclosure is not limited to the contents described in the above embodiment, but can be practiced in any form for achieving the purpose of the present disclosure and the related or attendant purpose, which may be, for example, the following: .

(1) The remote monitoring system and the remote monitoring method described in the first to fifth embodiments can be applied to various electric devices such as home appliances (for example, a television, a personal computer) other than the air conditioner.
(2) The remote monitoring system and the remote monitoring method described in the first to fifth embodiments can be applied to various buildings such as a hotel or a hospital having a room where electric devices other than an apartment are installed. is there.

(3) The remote monitoring system and the remote monitoring method described in the first to fifth embodiments are applicable to charging processing for one or more electric devices.
(4) In the first to fifth embodiments, although the prepaid system (prepaid system) has been described as an example of the charging process, it may be a postpaid system (postpaid system).

(5) In the first to fifth embodiments, the communication disconnection detection unit 230 is described as being provided in the first communication device, but the present invention is not limited to this, and may be provided in the server device.
(6) Each component of each device of the remote monitoring system in the first to fifth embodiments may be realized by LSI (Large Scale Integration) which is an integrated circuit. At this time, each component may be individually made into one chip, or may be made into one chip so as to include part or all. Further, although an LSI is used here, it may be called an IC (Integrated Circuit), a system LSI, a super LSI, or an ultra LSI depending on the degree of integration. Further, the method of circuit integration is not limited to LSI's, and implementation using dedicated circuitry or general purpose processors is also possible. A reconfigurable processor which can reconfigure connection or setting of circuit cells in an FPGA (field programmable gate array) or an LSI may be used. Further, if integrated circuit technology comes out to replace LSI's as a result of the advancement of semiconductor technology or a derivative other technology, it is naturally also possible to carry out function block integration using this technology.

(7) At least a part of the operation procedure of each device of the remote monitoring system described in the first to fifth embodiments and the like is described in a program, for example, a CPU (Central Processing Unit) stored in a memory The program may be read and executed. Further, the program may be stored in a recording medium and distributed.
(8) The contents described in the first to fifth embodiments may be combined as appropriate.

<< supplement (the 2) >>
The remote monitoring method and the remote monitoring system according to each embodiment and supplement (part 1) are summarized.
(1) In the first aspect, a first communication device connected to a server device that performs charging processing according to the power supply state of the electric device, and the first communication device connected to the first communication device via a wireless communication network, the electric device A remote communication system including a second communication device for monitoring a power state of the electronic device, wherein the first communication device receives power from the second communication device from the second communication device via the wireless communication network. When the on information indicating that the off state has been changed to the on state is received, the server apparatus causes the server apparatus to start billing processing for the user of the electric device, and the server apparatus causes the start process to start; (2) When it is detected that the wireless communication with the second communication device is interrupted, the server device causes the charging process to end, and the second communication device turns off the power of the electric device. When it is detected that the state is changed to the on state, the on information is transmitted to the first communication device via the wireless communication network, and wireless communication with the first communication device continues. A remote monitoring method of maintaining the power of the electric device in the on state during the on period, and switching the power of the electric device from the on state to the off state when detecting that the wireless communication with the first communication device is interrupted. is there.
According to the first aspect, it is possible to charge according to the use of the user's electrical device without using a prepaid card. Further, it is possible to prevent unauthorized use of the electric device by interrupting wireless communication between the first communication device and the second communication device, and it is possible to perform charging processing according to the power supply state of the electric device.

(2) According to the second aspect, in the remote monitoring method according to the first aspect, the second communication device receives power from the electric device while the wireless communication with the first communication device continues. When it is detected that the state is changed to the off state, the off information indicating the change is transmitted to the first communication device, and the first communication device continues the wireless communication with the second communication device. The remote monitoring method may cause the server device to end the charging process when the off information is received from the second communication device.
(3) According to the third aspect, in the first aspect or the second aspect, after the wireless communication with the second communication device is interrupted, the first communication device may interrupt the wireless communication after the first communication device is interrupted. It is determined whether or not the threshold time is equal to or more than the threshold value, and the server device is caused to continue the charging process if the blocking time is less than the first threshold value; It is a remote monitoring method that terminates the charging process.
According to the third aspect, frequent termination of the charging process can be prevented.

(4) According to a fourth aspect, in any one of the first aspect to the third aspect, the second communication device interrupts the wireless communication after the wireless communication with the first communication device is interrupted. Is determined to be equal to or greater than a second threshold, which is a value equal to or less than a first threshold, and if the shutoff time is not equal to or greater than the second threshold, the power of the electric device is maintained in an on state It is a remote monitoring method which switches the power supply of the said electric equipment from an ON state to an OFF state as it is more than a 2nd threshold value.
According to the fourth aspect, it is possible to prevent frequent forced power off of the electric device.
(5) A fifth aspect is the remote monitoring method according to the third aspect, wherein the first threshold is a value larger than an average value of radio blocking continuation time occurring in wireless communication in a normal operation state.
According to the fifth aspect, frequent termination of the charging process can be prevented.

(6) A sixth aspect is the remote monitoring method according to the third aspect or the fifth aspect, wherein the first threshold is a value smaller than a minimum charging time corresponding to the minimum unit of the charging process.
According to the sixth aspect, it is possible to carry out the charging process in the minimum unit of charging before and after the occurrence of the communication interruption.
(7) A seventh aspect is the remote monitoring method according to the fourth aspect, wherein the second threshold is a value larger than an average value of radio blocking continuation time occurring in wireless communication in a normal operation state.
According to the seventh aspect, it is possible to prevent frequent forced power off of the electric device.

(8) The eighth aspect is the remote monitoring method according to the fourth aspect or the seventh aspect, wherein the second threshold is a value smaller than a minimum charging time corresponding to the minimum unit of the charging process.
According to the eighth aspect, it is possible to carry out the charging process with the minimum unit of charging before and after the occurrence of the communication interruption.
(9) According to a ninth aspect, in any one of the first aspect to the eighth aspect, the electric device is an air conditioning system, and charging processing is performed in the server device while the power of the air conditioning system is on. Is a remote monitoring method where

(10) A tenth aspect relates to a first communication device connected to a server device that performs charging processing according to a power supply state of the electric device, and the first communication device connected to the first communication device via a wireless communication network, the electric device A remote communication system including a second communication device for monitoring a power state of the server, wherein the first communication device receives the on information from the second communication device via the wireless communication network; After the apparatus starts charging processing for the user of the electric device and the server apparatus starts the start processing, the server detects that the wireless communication with the second communication apparatus is interrupted. When the apparatus ends the charging process and the second communication apparatus detects that the power of the electric device is changed from the off state to the on state, the on information indicating the change is Transmitting power to the first communication device via the wireless communication network, and maintaining the power of the electric device in an on state during a period in which wireless communication with the first communication device is continued, the first communication It is a remote monitoring system which switches the power supply of the said electric equipment from an ON state to an OFF state, when it detects that wireless communications with an apparatus interrupted.
According to the tenth aspect, it is possible to charge according to the use of the user's electric device without using the prepaid card. Further, it is possible to prevent unauthorized use of the electric device by interrupting wireless communication between the first communication device and the second communication device, and it is possible to perform charging processing according to the power supply state of the electric device.

(11) An eleventh aspect is a first communication device connected to a server device that performs charging processing according to a power state of the electric device, the second communication device monitoring the power state of the electric device and wireless communication A wireless communication unit connected via a network and receiving, from the second communication device, on information indicating that the power of the electric device has been switched from the off state to the on state, and detecting a communication interruption of the wireless communication network After the detection unit and the wireless communication unit receive the on information, the server apparatus transmits a start signal for starting the charging process for the electric device, and the server apparatus transmits the start signal. A stop for causing the server device to end the charging process when the detection unit detects that the wireless communication unit has interrupted the wireless communication with the second communication device. And a control unit for transmitting signals, a first communication device.
According to the eleventh aspect, it becomes possible to charge according to the use of the user's electric device without using the prepaid card.

(12) In a twelfth aspect according to the eleventh aspect, the power supply of the electric device is changed from the on state to the off state from the second communication device during a period in which wireless communication with the second communication device is continued. It is a 1st communication apparatus which the said control part transmits the said stop signal to the said server apparatus, when the said wireless communication part receives the OFF information which shows the said thing.
(13) In a thirteenth aspect, in the eleventh aspect or the twelfth aspect, after the detection unit detects that the wireless communication has been interrupted, the control unit determines that the interruption time for the wireless communication is equal to or greater than the first threshold If the shutoff time is less than the first threshold, the server apparatus continues the charging process without transmitting the stop signal, and the shutoff time is the first threshold or more. And the first communication device that transmits the stop signal to the server device.
According to the first communication device of the thirteenth aspect, it is possible to prevent a situation where the termination of the charging process frequently occurs.

(14) According to a fourteenth aspect of the present invention, there is provided a wireless communication unit for performing wireless communication with a first communication device connected to a server apparatus that performs charging processing according to a power supply condition of an electrical device, and a power supply for monitoring the power condition of the electrical device. The wireless communication includes: a monitoring unit; and a power control unit configured to control a power state of the electrical device, wherein the power monitoring portion detects that the power of the electrical device is changed from the off state to the on state. The unit is the on information indicating the change, and the first communication device transmits the on information for causing the server device to start the charging process of the electric device to the first communication device, and the power control unit While the wireless communication unit continues the wireless communication with the first communication device, the power of the electric device is maintained in the ON state, and the wireless communication unit performs wireless communication with the controller. Detect shut off Switching off state the power of the electrical device from the ON state when the a second communication device.
According to the fourteenth aspect, it is possible to charge according to the use of the user's electrical device without using a prepaid card. Further, it is possible to prevent unauthorized use of the electric device by interrupting wireless communication between the first communication device and the second communication device, and it is possible to perform charging processing according to the power supply state of the electric device.

(15) The fifteenth aspect is the fourteenth aspect, wherein, when the power supply monitoring unit detects that the power supply state of the electric device has been changed from the on state to the off state, the wireless communication unit indicates the change The second communication apparatus is the second communication apparatus, wherein the first communication apparatus transmits, to the first communication apparatus, the off information for causing the server apparatus to end the charge processing of the electric device.
(16) A sixteenth aspect according to the fourteenth or fifteenth aspect, wherein the second communication device detects that the wireless communication unit has blocked the wireless communication, and then the blocking time of the wireless communication is determined It is determined whether or not the second threshold is exceeded, and the power control unit maintains the power of the electric device in the on state if the shutoff time is not the second threshold or more, and the shutoff time is the second threshold It is a 2nd communication apparatus which changes the power supply of the said electric equipment from an ON state to an OFF state as it is above.
According to the sixteenth aspect, it is possible to prevent frequent forced power off of the electric device.

(17) A seventeenth aspect is a server apparatus for remotely monitoring a power supply state of an apparatus via a wireless communication network, the communication unit connected to a communication system including the wireless communication network, and the power supply state of the electric apparatus A monitoring unit that monitors the wireless communication network and the communication unit, wherein the monitoring unit indicates that the power state of the electric device is changed from the off state to the on state. The charging process for the use of the electric device is started when it is detected through the communication unit, and the period during which the power state of the device is detected through the wireless communication network and the communication unit is started. The charging process is continued, and the fact that the power supply state of the device has been switched from the on state to the off state is indicated via the wireless communication network and the communication unit. Terminating the charging process when issuing a server device.
According to the seventeenth aspect, it is possible to charge according to the use of the user's electric device without using the prepaid card.
(18) An eighteenth aspect relates to the remote monitoring method according to the first aspect, wherein the power of the electric device is turned off via the wireless communication network when the charge balance of the user who uses the electric device runs out. It is.
According to the eighteenth aspect, it is possible to prevent the use of the electric device by the user in the situation where there is no charge balance.

(19) A nineteenth aspect according to the fourth aspect, wherein the second communication device determines that the second communication cutoff has continued for at least the second threshold, and the first communication device and the second communication device When it is detected that the power state of the electric device has been switched from the off state to the on state in a period until detection of normal wireless communication in the wireless communication path between , Remote monitoring method.
According to the remote monitoring method of the nineteenth aspect, the server apparatus can not charge for a period from when it is determined that the second communication interruption has continued for the second threshold or more to when normal wireless communication is detected. By preventing the use of the device, it is possible to avoid a situation where charging can not be performed despite the use of the electrical device.

(20) In a twentieth aspect, in the third aspect, the first communication device and the second communication device are determined after the second communication device determines that the second communication cutoff has continued for at least the second threshold. The remote monitoring method repeatedly performs the process of turning off the power of the electric device during the period until the normal wireless communication in the wireless communication path between the above and the above is detected.
According to the twentieth aspect, the server apparatus can not charge for a period from when it is determined that the second communication interruption has continued for the second threshold or more to when normal wireless communication is detected. It is possible to prevent situations that can not be charged despite the use of electrical devices.

(21) The twenty-first aspect relates to any one of the first aspect, the fourth aspect, the tenth aspect and the fourteenth aspect, wherein the second communication device performs a process of turning off the power of the electric device. In this case, it is a remote monitoring method for notifying the user of that.
According to the twenty-first aspect, it is possible to avoid a situation where the user misunderstands that the electric device has failed if the power of the electric device is forcibly turned off.
(22) In a twenty-second aspect according to any one of the third aspect, the fifth aspect, the sixth aspect and the thirteenth aspect, in the server apparatus or the first communication apparatus, the first communication interruption may be caused by the first communication interruption. When it is determined that the wireless communication path between the first communication device and the second communication device is detected after the determination that the threshold value or more has been continued, the power state of the electric device is the first communication. It is a remote monitoring method which makes it the power supply state before it determines with interruption | blocking having continued more than the said 1st threshold value.
According to the twenty-second aspect, the user's operation to turn on the power of the electric device is not necessary, and the burden on the user can be reduced.

(23) In the twenty-third aspect, in any one of the fourth aspect, the seventh aspect, the eighth aspect and the sixteenth aspect, the second communication apparatus continues the second communication cutoff continued for at least the second threshold. If it is determined that normal wireless communication in the wireless communication path between the first communication device and the second communication device is detected after the determination that the second communication cutoff is the second threshold, the power state of the electric device is the second threshold. This is a remote monitoring method for setting the power state before it is determined that the above continues.
According to the twenty-third aspect, the user's operation for turning on the power of the electric device is not necessary, and the burden on the user can be reduced.
(24) A twenty-fourth aspect is the remote monitoring method according to any one of the first aspect to the eighth aspect and the tenth aspect to the twenty-third aspect, wherein the electric device is a home appliance.

(25) A twenty-fifth aspect is the server device according to the seventeenth aspect, wherein the monitoring unit ends the charging process and updates the charging information stored in the management table.
According to the twenty-fifth aspect, it is possible to charge according to the use of the user's electrical device without using a prepaid card.
(26) The twenty-sixth aspect is the seventeenth aspect, further comprising a communication disconnection detection unit that determines whether the communication disconnection has continued for a predetermined time or more when communication disconnection of wireless communication in the wireless communication network is detected. The monitoring unit is a server device that stops the charging process based on a determination that the communication interruption has continued for the predetermined time or longer when the power supply state of the electric device is in the on state.

  According to the present disclosure, charging processing can be performed according to the use of the user's electric device without using a prepaid card, and unauthorized use of the electric device by blocking wireless communication is suppressed.

Reference Signs List 1 remote monitoring system 100 server device 110 communication unit 120 charging database 130 registration unit 140 monitoring unit 200 first communication device 210 communication unit 220 wireless communication unit 230 communication disconnection detection unit 300 second communication device 310 wireless communication unit 320 communication unit 330 communication Shutdown detection unit 340 Power status monitoring unit 350 Forced power off control unit 400 Air conditioner 410 Power supply unit 420 Communication unit 430 Power control unit 500 User terminal

Claims (3)

A first communication device connected to a server device that performs charging processing according to a power supply state of an electric device, and a first communication device connected to the first communication device via a wireless communication network and monitoring the power state of the electric device A second communication device in the remote monitoring system including the communication device, wherein
The first communication device is
When the on-information indicating that the power of the electric device is changed from the off state to the on state is received from the second communication device via the wireless communication network, the server apparatus charges the user of the electric device To start
After having the server apparatus start the start process, when it is detected that the wireless communication with the second communication apparatus has been interrupted, the server apparatus causes the accounting process to end.
The second communication device is
A wireless communication unit that performs wireless communication with the first communication device;
A power supply monitoring unit that monitors a power supply state of the electric device;
A power control unit that controls a power state of the electric device;
When the power supply monitoring unit detects that the power of the electric device is changed from the off state to the on state, the wireless communication unit is on information indicating the change, and the first communication device is the server. Sending, to the first communication device, on information for causing the device to start charging processing of the electric device;
The power control unit maintains the power of the electric device in the on state while the wireless communication unit continues the wireless communication with the first communication device, and the wireless communication unit is configured to perform the first communication When it is detected that the wireless communication with the communication device is interrupted, the power of the electric device is switched from the on state to the off state.
Second communication device. When the power supply monitoring unit detects that the power supply state of the electric device has been changed from the on state to the off state, the wireless communication unit is the off information indicating the change, and the first communication device is the one Transmitting, to the first communication device, off information for causing the server device to end the charging process of the electric device;
The second communication device according to claim 1. The second communication device is
After detecting that the wireless communication is interrupted, the wireless communication unit determines whether the interruption time of the wireless communication is equal to or more than a predetermined threshold value.
The power control unit maintains the power of the electric device in the on state if the shutoff time is not the predetermined threshold or more, and the power of the electric device is in the on state if the shutoff time is the predetermined threshold or more Switch to the off state
The second communication device according to claim 1.

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