KR20050031959A - Controller, program and memory media - Google Patents

Abstract

A controller, a program, and memory media are provided to define an execution rule, and to set the execution rule that describes state variables, conditions, and controlled contents in the controller, thereby carrying out an affiliated control between a monitored destination apparatus and a controlled destination apparatus. A rule generator(103) generates an execution rule according to affiliated control data transmitted from a user IF unit(102). The execution rule is stored in an execution rule DB(106). When a state report is received from an apparatus, a state signal receiver(107) sends state variables of the apparatus and variable values to a rule execution unit(105). The rule execution unit(105) extracts the execution rule interfaced with the sent variables and the values from the execution rule DB(106), and sends controlled contents to a device controller(108).

Description

Controller, Program, and Storage Media {CONTROLLER, PROGRAM AND MEMORY MEDIA}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a controller for controlling a device in accordance with a command input from a user, and is particularly suitable for use in cooperative control of a plurality of home devices.

In recent years, a so-called network home appliance system for controlling home appliances via a home network has been proposed and standardized. This system controls a target device by connecting a controller such as a home server to a home network and sending a control command from the controller. Here, the communication between the controller and the devices in the home is performed using a communication protocol such as ECHONET, UPnP, or SCP. As the communication network, a power supply line for supplying power to the devices in each home is used. In other words, by connecting the outlets of the home appliances and the controller to the power supply terminals, the home appliances and the controller are connected to the home network.

Moreover, as an example of a structure of such a network system, the thing of the following patent document 1 is known, for example.

Patent Document 1: Japanese Patent Application Laid-Open No. 10-276478

In the home network system, for example, a scene in which a plurality of home appliances are cooperatively controlled with each other, such as turning on lighting devices in the living room when the electric blinds of the living room is closed, is assumed.

However, in existing technologies such as UPnP, such cooperative control cannot be performed smoothly and simply. That is, the conventional UPnP is composed of a control point (CP) for outputting a device control signal, and one or a plurality of devices (in-home devices in a home network system) controlled by the CP, the control of the device is individually CP This is realized by outputting a control signal to the device and receiving the response from the device. That is, the CP and the individual devices are in one-to-one correspondence. Therefore, in order to perform cooperative control between the devices, an application must be created for the CP to operate by combining a plurality of control signals. In this case, a program technique for describing an application program is required. Therefore, complicated work is required in order to set up one cooperative control.

In addition, in UPnP, when a new device is added, a function owned by the device is declared from the device to the CP. However, when this function is included in the cooperative control between other devices, the existing application program is modified or renewed. It has to be created, which requires more complicated work.

Therefore, an object of the present invention is to provide a controller capable of smoothly and simply performing cooperative control between devices without requiring such a complicated work.

The present invention defines an execution rule including a state variable of a monitoring destination device, a condition to be met by the state variable, and a control content of the control destination device to be executed when the condition is satisfied. By setting an execution rule describing the control contents in the controller, the cooperative control between the monitoring destination device and the control destination device is performed.

The characteristics of each invention are as follows.

The present invention grasps the invention as a controller, which executes an input rule for setting up cooperative control between devices and an execution rule for generating an execution rule for cooperative control between devices from the cooperative control information inputted from the input means. The generation means, the execution rule storage means for dividing and storing the execution rules generated by the execution rule generation means for each execution rule, and the execution rule group stored in the execution rule storage means and the state information supplied from the device, And execution rule extracting means for extracting an execution rule suitable for the state information, and device control means for controlling the control target device based on the execution rule extracted by the execution rule extracting means. Here, the execution rule generated by the execution rule generating means includes a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and control contents of the control destination device to be executed when the condition is satisfied. have. The execution rule extracting means compares the state variable and its value among the state information supplied from the device with the state variable of each of the execution rules stored in the execution rule storage means and the conditions thereof, and compares them with each other. An execution rule is extracted from the execution rule group among the execution rule storage means, and the control means controls the control destination device in accordance with the control contents of the control destination device included in the execution rule extracted by the execution rule output means. do.

In the controller according to the present invention, the device is connected to a local area network (LAN) such as a home network, the execution rule extracting means receives state information from the device via the network, and the control means is the network. The control target device is controlled by transmitting a control signal through the controller.

In the controller according to the present invention, the state variable of the monitoring destination device included in the execution rule includes information for identifying the state variable, information for identifying the type of the monitoring destination device, and installation of the monitoring destination device. Contains information to identify the place. The execution rule extracting means may further include information for identifying a state variable, information for identifying the type of the device, information for identifying an installation location of the device, from the state information received from the device, Information including the value of the state variable is generated, the generated information is compared with the execution rule group, and an execution rule matching the generated information is extracted from the execution rule group among the execution rule storage means.

In the controller according to the present invention, the control content of the control destination device included in the execution rule is defined as a state variable and its value of the control destination device, and the state variable is associated with information for identifying the state variable. , Information for identifying the type of the monitoring destination device, and information for identifying the installation place of the monitoring destination device. The control means specifies the control target device from the information for identifying the type of the monitoring destination device included as the control content and the information for identifying the installation location of the monitoring destination device. The control contents of the control target device are determined from the state variables and the values included therein.

In the controller according to the present invention, the execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed. After the control means executes the control according to the execution rule, the control means deletes the execution rule in accordance with the mode setting information with reference to the mode setting information included in the execution rule.

In the controller according to the present invention, the execution rule generated by the execution rule generating means includes a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and the execution rule storage means when the condition is satisfied. And information specifying the execution rule to be erased.

In the controller according to the present invention, when the cooperative control is set such that the control operation of the control destination device is executed when each setting condition set in the plurality of monitoring destination devices is satisfied, the execution rule is set for each setting condition of the monitoring destination device. Each of the prepared and prepared execution rules includes a state variable and a condition of the monitoring destination device and information for associating the prepared execution rule.

In the controller according to the present invention, the execution rule storage means stores the execution rule group separately for each state variable of the monitoring destination device.

In the controller according to the present invention, the execution rule storage means includes, with respect to the state variables of the same monitoring destination device, a condition that the state variable must satisfy and control contents of the control destination device executed when the condition is satisfied. The data structure of the storage information is configured so that a plurality of sets can be stored in correspondence with each other, and when an execution rule is generated by the execution rule generating means, the condition that the state variable of the monitoring destination device must satisfy from the execution rule, It is characterized by extracting the control contents of the control destination device to be executed when the above condition is satisfied, and constructing a pair, and storing the pair corresponding to the state variable of the corresponding monitoring destination device.

In the controller according to the present invention, the execution rule extracting means compares the state variable among the state information supplied from the device with the state variable of the monitoring destination device that distinguishes the execution rule group stored in the execution rule storing means, Specifies a state variable of the monitored destination device that matches with each other and includes a condition corresponding to a value of the state variable in the state information supplied from the device among the execution rule groups corresponding to the specified state variable of the monitored destination device. It is characterized in that the extraction.

In the controller according to the present invention, the execution rule storing means searches for the division of the state variable corresponding to the state variable of the monitoring destination device among the execution rules generated by the execution rule generating means when storing the execution rule, Comparing the condition-control content set belonging to the searched category with the condition and control content of the execution rule to be stored, discriminating whether there is any contradiction, and controlling the memory according to the discrimination result. It is done.

In the controller according to the present invention, the execution rule storing means compares the pairs of the condition-control contents belonging to the division of the state variable of the monitoring destination device among the already executed execution rule groups, and detects the pairs with mutual contradictions. It is characterized by controlling the stored information already stored according to the detection result.

In the controller according to the present invention, the execution rule storage means determines that there is a contradiction between the execution rules when the conditions are duplicated and the control contents are different.

In the present invention, the present invention is understood as a program and is a program for imparting at least the functions of the above-described means to a computer.

In the present invention, the present invention is understood as a storage medium, and at least, it is a storage medium storing a program for imparting the functions of the above-described means to a computer.

In addition, the present invention is not only limited to cooperative control of devices in the home, but also applicable to cooperative control between other devices.

The features, technical meanings, and effects of the present invention will become more apparent from the following description of the embodiments. However, the following embodiment is only one embodiment of this invention to the last, The meaning of the term of this invention-each structural requirement, etc. are not restrict | limited to what was described in the following embodiment.

<Embodiment>

EMBODIMENT OF THE INVENTION Hereinafter, embodiment of this invention is described with reference to drawings.

(Example 1)

1 shows a configuration of a home network system according to the first embodiment.

In this embodiment, the controller 100 and home appliances 1a to 1c, 2a to 2g, ... are connected via a home network. Here, communication protocols such as ECHONET, UPnP, SCP and the like can be used for the communication between the controller 100 and the home devices 1a to 1c, 2a to 2g, ... as in the conventional example. As the communication network, a power supply line for supplying power to the devices in each home can be used.

In addition, the controller 100 according to the present embodiment can be implemented by hardware, CPU, memory, other LSI, or the like of any computer. Moreover, in software, it can implement | achieve by the program etc. with a recording control function loaded in the memory. 1, the functional blocks of the controller 100 realized by hardware and software are shown. It goes without saying that these functional blocks can be realized in various forms such as only hardware, only software, or a combination thereof.

As shown in FIG. 1, the controller 100 includes a communication control unit 101, a user IF unit 102, a rule generation unit 103, a device DB 104, a rule execution unit 105, And an execution rule DB 106, a state signal receiving unit 107, and a device control unit 108.

The communication control unit 101 controls data communication through an external communication network such as the Internet. Here, when the communication control unit 101 receives data for cooperation control from the outside, the communication control unit 101 outputs this to the rule generation unit 103. Moreover, the user ID of the sender user and its password are attached to this association control data. The communication control unit 101 sends these user IDs and passwords to the rule generation unit 103 together with the cooperation control data.

The user IF unit 103 presents the user with an input screen composed of a cooperative control setting input screen, for example, a GUI (Graphic User Interface) or the like. Then, the association control data input through this input screen is output to the rule generation unit 102. The input screen also includes an item for requesting input of a user ID and password. Therefore, the user's user ID and password are simultaneously input from the user together with the association control data. The user IF unit 101 sends these user IDs and passwords to the rule generation unit 103 together with the association control data.

The rule generation unit 103 generates an execution rule (described later) according to the association control data received from the user IF unit 103 or the communication control unit 101, and outputs it to the rule execution unit 104. At this time, the application of the authority to set such association control is verified by comparing the user ID and password received from the communication control unit 101 or the user IF unit 102 with the user ID and password stored in the device DB. . Here, the device DB 104 is a database that stores information of devices in the home connected to the home network.

2 shows a configuration of data stored in the device DB 104. The device DB 104 includes a name (device name) of a device in the home, an installation location (location) of the device in the home, identification information (user ID) of a user who can use the device in the home, and a password thereof. Are stored separately for each device. In addition, when the device in the home is connected to the home network, the device DB 104 registers the information of the device shown in FIG. 2 automatically or manually.

The rule generation unit 103 generates the user ID and password of the control destination device before generating the execution rule based on the association control data received from the communication control unit 101 or the user IF unit 102. Extracted from the communication control unit 101 and verify that they match the user ID and password received from the communication control unit 101 or the user IF unit 102. When there is a match, an execution rule is generated based on the received association control data and output to the rule execution unit 105. On the other hand, when there is a mismatch, an error notification is sent to the communication control unit 101 or the user IF unit 102.

Returning to FIG. 1, the rule execution unit 105 registers the execution rule received from the rule generation unit 103 in the execution rule DB 106. In addition, upon receiving the state data (event) from the state signal receiving unit 107, the control data (action) is appropriately output to the device control unit 108 with reference to the execution rule registered in the execution rule DB 106. In addition, the structure of an event and an action, and the process by the rule execution part 105 are demonstrated in detail next. The configuration of data registered in the execution rule DB 106 will also be described in detail later.

The status signal receiver 107 receives status data (which accompanies communication protocols such as ECHONET, UPnP, SCP, etc.) received from home devices 1a to 1c, 2a to 2g, ... through a home network and receives status data (events). ), And output this to the rule execution unit 105.

The device control unit 108 converts the control data (action) received from the rule execution unit 105 into control signals (which accompany communication protocols such as ECHONET, UPnP, SCP, etc.) and, via the home network, control targets. To your home device. When a control signal is transmitted to a device that does not transmit a state signal (for example, the lighting device 2g of FIG. 1), the control signal is generated on behalf of the state of the control operation. The status data (event) is sent to the rule execution unit 105. Incidentally, whether the control destination device is a device that transmits a status signal is determined by referring to a management table that describes, for example, the functions and specifications of the home device. This management table may be incorporated in the device control unit 108, in addition to the form incorporated in the device control unit 108, and may be referred to as a reference form.

Next, with reference to FIG. 3, the structure of an event and the structure of an execution rule are demonstrated.

Fig. 3A shows the structure of the event. Here, an event is a minimum data unit for defining an object (device state: described later), and is composed of an event clause for identifying an object and "Value" for defining the content of the object.

In general, in the case of performing cooperative control between devices, a control mode for changing the state of another device (control destination device) is taken when one device (monitoring destination device) is present. In the present embodiment, the state of the monitoring destination device and the state of the control destination device are grasped by a common concept of "object", and this concept is expressed in a data unit of "event".

Therefore, the state of the monitoring destination device and the state of the control destination device are both represented by an event. For example, in the case of setting the cooperative control of "turning the cooling of the living room ON when the temperature of the living room is 26 degrees", and setting the monitoring target device as the thermometer and the control destination device as the air conditioner, the temperature state of the thermometer and The driving state is represented together by the event.

In addition, as shown in Fig. 3A, events are divided into Name, Device, Location, and Value.

Among them, "Name" defines the state variable of the device. For example, if the apparatus is an air conditioner, it is "cooling", "heating", "dehumidification", "ventilation", or the like. "Device" also defines the name of the device. Examples are air conditioners, thermometers, DVDs, and the like. In addition, "Location" defines the installation location of the device. For example, the living room, the entrance, the children's room 1, the children's room 2, and the like. In addition, "Value" prescribes the content (value) of the state variable specified by "Name". For example, when "Name" is temperature, it is "26 degree", and when "Name" is cooling, it is "ON" etc.

In the cooperative control, such an event indicates the content of the object at the present time in the monitoring destination device if it is a monitoring destination device, and indicates the content of the object after control at the control destination device if it is a control destination device. For example, as described above, in the case of setting the cooperative control of "turning the cooling of the living room ON when the temperature of the living room is 26 degrees", the monitoring destination object is set to Name = Temperature, Device = Thermometer, Location = Living Room, and Value = 26. The control destination object is set to Name = cooling, Device = air conditioning, Location = living room, and Value = ON.

In this embodiment, such cooperative control is defined by the execution rule shown in Fig. 3B.

Here, one execution rule is comprised of an event, a condition, and an action, as shown in FIG. In the event, the event clause of the monitoring destination object is described. In addition, the condition describes a judgment condition based on the value of the monitoring destination object. In addition, the action describes the event of the control destination object as it is. This execution rule is generated by the rule generation unit 103 as described above. The generated execution rule is registered in the execution rule DB 106 sequentially.

4 shows an example of the configuration of an execution rule registered in the execution rule DB 106.

In Fig. 4, rule No. 001 registers the above-described execution rule of "turning on cooling of the living room when the temperature of the living room becomes 26 degrees or more." That is, in the event of the execution rule, Name = temperature, Device = thermometer, and Location = living room are described as the event clause of the monitoring destination object. In the condition, Value = 26 degrees or more is described as the value of the monitoring destination object. The action describes Name = cooling, Device = air conditioning, Location = living room, and Value = ON as the event of the control destination object.

In addition, three or more devices can be cooperatively controlled using this execution rule.

"A" shown in FIG. 4 exemplifies an execution rule at the time of cooperative control of three devices consecutively. That is, by the execution rule of rule No. 002 and the execution rule of rule No. 003, the cooperative control is set to "turn on the door light and close the blind of a living room at 6 pm."

Here, in the execution rule of rule No. 002, the cooperative control "turns on the door light at 6 pm" is set, and in the execution rule of rule No. 003, "when the illumination of the entrance light turns on, electric power of the living room is set." Close blind ”is set. Therefore, when the execution rule of rule No.002 is executed, the execution rule of rule No.003 continues to be executed, whereby the clock, the lighting device, and the electric blind are cooperatively controlled in a series of flows.

In addition, "B" shown in FIG. 4 exemplifies an execution rule when cooperatively controlling other devices under the condition of two devices. That is, by the execution rule of the rule No.010 and the execution rule of the rule No.011, the cooperative control of "the electric blind of the living room is closed and when the detection sensor of a living room detects a person turns on the lighting of a living room" is set. It is.

Here, in the execution rule of rule No.010, the event of the monitoring destination object is described as "event" and "condition" as in the normal cooperative control, but the action is a jump destination execution rule instead of the event of the control destination object. Rule No. 011 is described. Thereby, "event" and "condition" of the monitoring destination apparatus (electric blind of the living room) described in rule No.010, "event" of the monitoring destination apparatus (living-sensing sensor) described in rule No.011, and When both of the "conditions" are satisfied at the same time, the "action" of the monitoring destination device (the living lighting device) described in rule No.012 is executed.

The execution rule is generated by the execution rule generator 103. At this time, from the communication control unit 101 or the user IF unit 102, data necessary for creating the execution rule, that is, data for specifying the object of the monitoring destination device and the control destination device, is the rule of association data. It is supplied to the generation part 103. For example, the input screen in the user IF unit 102 includes an input item for acquiring these data.

Next, the operation at the time of cooperative control in the home network system will be described with reference to the flowchart of FIG. 5.

When receiving a status notification (status signal) from a device connected to the home network (S201, S101), the status signal receiver 107 converts the status notification into an event (S102), which is executed by the rule execution unit 105. Send to. The rule execution unit 105 compares the event clause of the received event with the " events " of each execution rule registered in the execution rule DB 106, and executes the " event " corresponding to the event clause. It is determined whether the rule is registered in the execution rule DB 106 (S104).

If the corresponding execution rule is not registered in the execution rule DB 104, the flow returns to S101 to wait for reception of the next status notification. On the other hand, when the corresponding execution rule is registered, the condition of the execution rule is compared with the value in the event received from the state signal receiving unit 107 (S105), and it is determined whether the value is suitable for the condition of the execution rule. (S106).

If the Value is not suitable for the condition, the flow returns to S101 to wait for reception of the next status notification. On the other hand, when the Value is suitable for the condition, the "action" of the execution rule is sent to the device control unit 108. The device control unit 108 specifies the control target device from the provisions of "Device" and "Location" among the received "actions", and grasps the control contents of the device from "Name" and "Value". Then, a control signal corresponding to the control content is generated and transmitted to the control destination device (S107).

When the control target device receives the control signal (S202), the control target device switches its operation state to the operation state according to the control signal (S203), and sends a status notification (status signal) indicating the operation state after the switching to the state signal receiving unit ( 107) (S204). The state signal receiving unit 107 converts the received state notification into an event and sends it to the rule execution unit 105 (S108). The rule execution unit 105 specifies the execution completion rule from the received event and deletes the execution completion execution rule from the execution rule DB (S109). The process then returns to S101 to wait for reception of the next status notification.

In addition, in S107, when a control signal is transmitted to the apparatus which does not transmit a status notification, the process of S202-S204 is abbreviate | omitted. At this time, assuming that the control operation is executed as the control target device, an event is generated by the device control unit 108, which is sent to the rule execution unit 105. The rule execution unit 105 performs the above-described processing of S108 based on these events.

As mentioned above, according to this embodiment, since the execution rule which describes "event", "condition", and "action" is produced | generated, and it is registered in the execution rule DB106, cooperative control between devices can be performed separately, It is possible to easily set up cooperative control between devices without generating a complicated application program.

In addition, even when a new device is connected to the home network, there is no need to modify or rewrite the existing execution rules other than those related to the device, and only modify the execution rules for the new device or generate new execution rules. Just do it.

(Example 2)

In the first embodiment, the execution completion execution rule is deleted from the execution rule DB 106. However, the deletion of the execution rule may be restricted by the user's setting. Specifically, as shown in Fig. 6, the "setting mode" is included in the data stored in the execution rule DB 106, and when the control data is input, the execution completion execution rule is erased according to the user's intention. Allows you to set randomly. In Fig. 6, when the setting mode is &quot; 1 &quot;, the erasure of the execution completion execution rule is restricted.

In this case, the processing flow at the time of cooperative control is changed as shown in FIG. That is, compared with the processing flow of FIG. 5, when S121 is added and a status notification is received from the controlling device (S108), only when the setting mode of the execution completion execution rule is "0" (S121), The execution completion execution rule is erased from the execution rule DB 106 (S109).

According to the modified example of FIG. 6 and FIG. 7, the effort which resets normally performed cooperative control every time can be reduced, and the procedure at the time of cooperative control setting can be further simplified.

(Example 3)

In the first embodiment, an event is generated from the status notification sent from the device, and the rule execution unit 105 interprets the event to specify the execution completion rule and delete the specified execution completion rule. As shown in Fig. 8, an execution rule (the execution rule of No. 004 in the drawing) for erasing the execution completion rule is registered in the execution rule DB 106, and the execution completion rule is executed based on this execution rule. It can also be deleted from the DB (106). According to this, there is no need to bear the processing burden of specifying the execution completion rule with respect to the rule execution part 105, and the process by the rule execution part 105 can be simplified.

In addition, in the case of "A" shown in Fig. 8, the cooperative control of "No. 002 and No. 003" is performed, "When 6 pm, the lighting of the front door is turned on and the blind of the living room is closed." If, by the execution of this alliance control, a status notification is sent from the electric blind that the living room blind is closed, the event according to the status notification, Name = open / closed state, Device = electric blind, Location = living room, Value = closed The status signal receiver 107 is sent to the rule execution unit 105. The execution rule of No. 002 matching this event is executed, and the execution rules of Nos. 002 to No. 004 are deleted from the execution rule DB 106 as the action.

Moreover, although the execution rule in which the condition was described was illustrated in the said embodiment, there may also be a form of the cooperative control which registers the execution rule in which the description of the condition was omitted in the execution rule DB 106. For example, when a specific (action) operation is executed on the controlled device when the state variable of the monitored device changes (but not on the condition of the change), only the "event" is described in the execution rule. NULL. At this time, if the status notification about the state variable described in "event" is transmitted from the monitoring target device, the control operation described in the action of the execution rule is executed uniformly regardless of the value of the state variable. .

(Example 4)

In the above embodiment, an execution rule is generated for each cooperative control and registered separately in the execution rule DB 106. Instead, as shown in FIG. 9, a plurality of types of conditions are provided for one common event. You may register a set of and an action. In this case, one association control is set by a set of conditions and actions (pairs).

For example, in Fig. 9, in Rule No. 001, the cooperative control regarding Name = temperature, Device = thermometer, and Location = living room event is registered for each pair. Among them, in pair No. 001, the condition and action of "When the temperature becomes 26 degrees or more, turn on cooling of the living room" is set, and in pair No. 002, "When the temperature becomes 23 degrees or less, The condition and action of "OFF cooling" are set.

In the figure, in Rule No. 033, the association control relating to the name = open / closed state, Device = electric blind, and Location = living event is registered for each pair. Among these, the pair No. 001 has a condition of "when the opening / closing state is closed, the pair of the pair No. 3 of the rule No. 12, and erases itself (pair of the pair No. 1 of the rule No. 33)" An action is set, and a condition and an action are set in pair No. 002, "executing control of pair No. 3 of rule No. 36 when the opening / closing state is closed."

Thus, in the present embodiment, the cooperative control is registered in pairs. Addition, deletion, and correction of association control are performed for each pair. In addition, the link of one control and the other control is also performed using a pair. The operation of adding and deleting pairs will next be described in detail with reference to a flowchart.

10 shows an example of the configuration of the controller 100 according to the present embodiment.

The controller 100 differs in the function of the rule execution unit 110 compared to the controller 100 shown in FIG. 1. That is, in addition to the function of the rule execution unit 105 of FIG. 1, the rule execution unit 110 executes an execution rule generated by the rule generation unit 103 already registered in the execution rule DB 106. A contradiction determination function for determining whether there is a contradiction with the rule (pair), and when there is no contradiction, the condition and action are extracted from the execution rule supplied from the rule generation unit 103 to form a pair, and the rule No corresponding thereto. It has a rule compositing feature that adds to.

In addition, the data structure of the execution rule DB 106 is changed as shown in FIG. About other structure, it is the same as that of FIG.

11 shows the processing operation at the time of registering the execution rule.

When the execution rule is generated by the rule generation unit 103 (S301), the rule execution unit 110 refers to the execution rule DB 106 (S302), and an event identical to the event of the generated execution rule is already executed. It is determined whether or not the rule exists in the rule DB 106 (S303). If it does not exist (S303: NO), the generated execution rule is newly registered in the execution rule DB 106 (S307). At this time, the condition and action of the execution rule are paired, and a pair No. = 001 is given to this (S309), and the execution rule DB 106 is registered.

On the other hand, when the same event as the event of the generated execution rule already exists in the execution rule DB 106 (S303: YES), the rule execution unit 110 sequentially refers to the pair belonging to the event. For example, if the generated execution rule is Name = temperature, Device = thermometer, Location = living room, pair 1, pair 2,... Belonging to rule No. 001 shown in FIG. See. Then, a pair matching the name, device, and location of the action of the generated execution rule is extracted (S304). Among the extracted pairs, the generated execution rule and the condition (Value) overlap, and the action (Value) is different. I determine whether a pair exists (S305). In addition, the condition (Value) overlaps, for example, when it is a perfect match, such as "26 degrees or more" and "26 degrees or more", or "26 degrees or more" and "27 degrees or more" or "26 degrees or more" "And" 27 degrees or less ".

If the determination in S305 is YES, the generated execution rule is inconsistent with the already registered execution rule (there is a relationship of control contradiction), and error output processing such as an error display is performed (S308). At this time, the generated execution rule is not registered in the execution rule DB 106.

For example, the generated execution rule may include an event (Name = temperature, Device = air conditioner, Location = living), condition (Value = 27 degrees or less), action (Name = cooling, Device = air conditioner, Location = living, Value = OFF), the pair No. 001 of rule No. 001 of FIG. 9 overlaps with the condition (Value = 26 degrees or more), and the action (Value = ON) is different. Therefore, the execution rule is the execution rule DB 106. ) Is not registered.

If the determination in S305 is "Yes", a pair is formed from the conditions and actions of the generated execution rule, and a pair No. is attached to this (S306) to execute so as to belong to the event (event equal to in S303). It registers in rule DB106. At this time, the rule execution unit 110 gives the pair the pair No. of which one is added to the final pair No. (= k) among the pairs belonging to the event (rule No.) (S306).

12 shows a processing operation when deleting an execution rule.

When the deletion processing is started, the rule execution unit 110 determines the rule No. And a pair to be deleted based on the pair No., and the pair is deleted from the execution rule DB 106 (S401). Subsequently, as a result of executing the deletion, the rule execution unit 110 determines whether the pair has remained in the rule No. to which the pair belongs (S402), and if it remains, the rule execution unit 110 is given to the remaining pair. The pair No. is numbered (S403). Specifically, when the pair of intermediate pairs is deleted, numbering is performed so that subsequent pair numbers are filled forward one by one so that the continuity of the pair numbers can be maintained. When the link state in the cooperative control becomes inadequate due to such deletion and numbering, the corresponding pair description is corrected so that the link state becomes an appropriate state (S404).

For example, in the pair No. 002 of the rule No. 033 of FIG. 9, when the pair No of the link destination pair (rule No. 036, the pair No. 003) is numbered from the pair No. 003 to the pair No. 002, The description of pair No. 002 of rule No. 033 is corrected to "link → rule 36 / pair 3" to "link → rule 36 / pair 2." When the link destination pair (rule No. 036, pair No. 003) is deleted, the description of the pair No. 002 of the rule No. 033 is corrected to "NULL".

On the other hand, when it is determined in S402 that a pair does not remain in the rule No., the rule execution unit 110 deletes the rule itself from the execution rule DB 106 (S405). In the same manner as above, the link is arranged in S404.

According to this embodiment, the processing burden at the time of execution of cooperative control can be remarkably reduced as compared with the first embodiment.

That is, in the first embodiment, since the execution rules are registered with no operation or individually, the execution rules corresponding to the event (status notification from the device) are searched by searching all the execution rules in the execution rule DB 106. It was necessary to extract. On the other hand, in the present embodiment, since pairs (conditions and actions) are integrated for each event, the event classification (rule No.) corresponding to the event (status notification from the device) is searched for, and It is only necessary to search for a corresponding pair from a group of pairs belonging to the division (rule number), and it is possible to efficiently extract the corresponding execution rule (pair) without searching all the execution rules.

In addition, as in the present embodiment, when pairs (conditions and actions) are integrated for each event, the effect of easily detecting a contradictory execution rule (pair) can also be achieved. In other words, the mutual contradiction between the execution rules need only be determined for the pair group of each event.

In the present embodiment, as described above, the mutual contradiction is detected at the time of registering the execution rule, and the registration of the contradictory execution rule (pair) is prevented in advance, but the execution rule (pair) is once registered and registered. You may detect a mutually contradictory pair later, and exclude a mutually contradictory pair. Also in this case, since only the pair of groups belonging to the event need to be detected, mutually contradictory detection is significantly simplified compared to the case where the execution rules are registered as no operation or individually as in the first embodiment. can do. Also in this case, as the detection method of mutual contradiction, for example, the processing method of S305 shown in FIG. 11 can be used.

In addition, as in the present embodiment, if pairs (conditions and actions) are integrated for each event, it is possible to simplify the task of maintaining an already registered execution rule. For example, in the case of maintaining the cooperative control for a specific event, only the pair of relevant events is examined, and maintenance can be performed very simply.

As described above, according to the present embodiment, it is possible to simplify the processing at the time of rule execution, to simplify the process of detecting the conflicting execution rules, and to simplify the work at the time of rule maintenance.

In the above description, the pair No. is numbered according to the deletion of the pair, but the pair No. of the deleted pair may be assigned to the pair registered thereafter for the event without performing the numbering process. By doing so, the link state between the pairs becomes unsuitable due to the numbering, thus eliminating the need to separately perform the process of correcting the description of the link source pair as described above.

In this case, the rule DB management table as shown in Fig. 13 may be used to manage the use status of the pair No. for each rule No. In Fig. 13, "1" of the flag indicates that the pair No. is in use, and "0" of the flag indicates that the pair is deleted and the pair No. becomes empty. Such a rule management table may be added separately to the execution rule DB 106, for example.

In this case, however, if the pair No. of the rule No. is in use, the pair No. of 1 added to the final pair No. (= k) is added to the newly added pair as in the above. do. When the link destination pair is deleted, it is necessary to change the description of the link source pair to NULL in the same manner as above. Otherwise, a pair that is independent of the link source pair will be linked.

In the above, in the case where a contradiction occurs between the pair to be newly registered and the pair already registered, the registration of the pair to be newly registered is invalidated. Instead, the already registered pair is deleted and newly You may validate the registration of the pair to be registered.

As mentioned above, although embodiment (Examples 1-4) concerning this invention was described, this invention is not limited to this embodiment, Of course, various changes are possible of course.

For example, in the above embodiment, user authentication is performed using a user ID and a password, but an authentication method such as fingerprint authentication may be used instead.

In the above embodiment, the event divided by Name, Device, Location, and Value is used to monitor the state change of the monitoring destination device and set the association control rule. However, the data structure of the event is an example. Other data structures may be employed as the data structure of the state change information expressed as an event in the embodiment and the data structure of the association control rule.

In addition, various changes are possible for embodiment of this invention suitably within the range of the technical idea described in the claim.

According to the present invention, since cooperative control is performed between the monitoring destination device and the control destination device by setting execution rules describing state variables, conditions, and control contents in the controller, the cooperation between the devices is not required without generating a complicated application program. The control can be set easily.

In addition, even when a new device is connected to the network, there is no need to modify or rewrite existing execution rules other than those related to the device, and to only modify the execution rules for the new device or generate new execution rules. It becomes only thing.

Furthermore, according to the present invention, by defining the monitoring destination device and its state condition, and the control destination device and its control state as the state variables of the device, the type of the device, the installation place of the device, and the value (condition) of the state variable, Each device connected to the network and its state can be specified smoothly or appropriately, and cooperative control can be efficiently performed. In particular, by managing the monitoring destination device and its condition conditions, and the control destination device and its control state by a common data unit (event), it is possible to simplify the process of collating the status of the monitoring destination device with the execution rule, and thus, cooperative control. The processing burden at the time can be reduced.

In addition, according to the present invention, if it is possible to set whether or not to cancel the execution rule, it is possible to reduce the trouble of resetting the cooperative control normally performed at each time, thereby simplifying the procedure at the cooperative control setting.

Further, according to the present invention, the execution rule generated by the execution rule generating means is deleted from the state variable of the monitoring destination device, the condition that the state variable must meet, and the execution rule storage means when the condition is satisfied. By including the information specifying the execution rule to be executed, the execution completion rule can be erased by the same processing as that of rule execution, and the deletion processing of the execution completion rule can be simplified.

Further, by setting the execution rule according to the present invention, it is possible to set the cooperative control in which the control operation of the control destination device is executed when all the setting conditions set in the plurality of monitoring destination devices are satisfied.

Further, according to the present invention, if the execution rule group is stored separately for each state variable of the monitoring destination device, the processing of extracting the execution rule at the time of cooperation control can be simplified. That is, according to the present invention, the monitoring destination, which is matched with each other by comparing the state variable among the state information supplied from the device with the state variable of the monitoring destination device that distinguishes the execution rule group stored in the execution rule storage means, is matched with each other. Execution rule storage by specifying a state variable of the device and extracting an execution rule including a condition corresponding to the value of the state variable from the state information supplied from the device among the execution rule groups corresponding to the state variable of the specific monitoring destination device; It is possible to extract the execution rules required for the cooperative control efficiently without searching all the execution rules stored in the means.

In addition, according to the present invention, the effect that the mutual contradiction between execution rules can be detected easily can be exerted. That is, according to the present invention, even if all the execution rules stored in the execution rule storage means are not retrieved, only the pair of condition-control contents belonging to the classification of the state variable of one monitoring destination device is examined. The mutual contradiction can be detected, and the process of detecting the mutual contradiction can be simplified.

In addition, according to the present invention, the effect of simplifying the maintenance work of the execution rule group can also be exerted simultaneously.

1 is a diagram showing the configuration of a home network system according to a first embodiment.

2 is a diagram showing a configuration of a device DB according to the first embodiment.

3 is a diagram showing the structure of an event and an execution rule according to the first embodiment;

4 is a diagram illustrating a configuration of an execution rule DB according to the first embodiment.

FIG. 5 is a diagram showing an operation during cooperative control according to the first embodiment; FIG.

6 is a diagram illustrating a configuration of an execution rule DB according to the second embodiment.

FIG. 7 is a diagram showing an operation during cooperative control according to the second embodiment; FIG.

8 is a diagram showing the configuration of an execution rule DB according to the third embodiment;

9 is a diagram showing a configuration of an execution rule DB according to the fourth embodiment.

10 is a diagram showing the configuration of a home network system according to a fifth embodiment;

Fig. 11 is a flowchart showing operation at the time of registering execution rule according to the fifth embodiment.

Fig. 12 is a flowchart showing the operation when deleting the execution rule according to the fifth embodiment;

Fig. 13 is a diagram showing the configuration of the rule DB management table according to the fifth embodiment.

<Explanation of symbols for the main parts of the drawings>

100: controller

101: communication control unit

102: user IF unit

103: rule generator

105: rule execution unit

106: execution rule DB

107: status signal receiving unit

108: device control unit

110: rule execution unit

Claims (17)

Input means for setting cooperation control between devices, execution rule generation means for generating execution rules for cooperation control between devices from the cooperation control information input from the input means, and execution generated by the execution rule generation means. Execution rule storage means for storing the rule, execution rule extracting means for comparing the state information supplied from the device with the execution rule group stored in the execution rule storage means, and extracting the execution rule suitable for the state information; A device control means for controlling the control target device based on the execution rule extracted by the extraction means, The execution rule generated by the execution rule generating means includes a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and control contents of a control destination device to be executed when the condition is satisfied, The execution rule extracting means compares the state variable and its value among the state information supplied from the device with the state variable of each of the execution rules stored in the execution rule storage means and the conditions thereof, and the execution rule in which both match each other. Is extracted from the execution rule group among the execution rule storage means, And the control means controls the control destination device in accordance with the control contents of the control destination device included in the execution rule extracted by the execution rule extracting means. The method of claim 1, The device is connected to a local area network (LAN) such as a home network, the execution rule extracting means receives status information from the device via the network, and the control means controls by transmitting a control signal through the network. A controller which controls the target device. The method of claim 2, The state variable of the monitoring destination device included in the execution rule includes information for identifying the state variable, information for identifying the type of the monitoring destination device, and information for identifying an installation location of the monitoring destination device. Including, The execution rule extracting means includes, from the state information received from the device, information for identifying a state variable, information for identifying a type of the device, information for identifying an installation location of the device, and the state. And generating information including a value of a variable and comparing the generated information with the execution rule group to extract the execution rule. The method of claim 2, The control content of the control destination device included in the execution rule is defined as a state variable of the control destination device and its value, and the state variable includes information for identifying the state variable and the type of the monitoring destination device. Information for identification and information for identifying an installation place of the monitoring destination device, The control means specifies a control target device from the information for identifying the type of the monitoring destination device included as the control content and the information for identifying the installation location of the monitoring destination device, and is included as the control content. And the control content of the control target device is determined from the state variable and the value thereof. The method of claim 3, The control content of the control destination device included in the execution rule is defined as a state variable of the control destination device and its value, and the state variable includes information for identifying the state variable and the type of the monitoring destination device. Information for identification and information for identifying an installation place of the monitoring destination device, The control means specifies a control target device from the information for identifying the type of the monitoring destination device included as the control content and the information for identifying the installation location of the monitoring destination device, and is included as the control content. And the control content of the control target device is determined from the state variable and the value thereof. The method of claim 1, The execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed, And the control means erases the execution rule in accordance with the mode setting information with reference to mode setting information included in the execution rule after executing the control according to the execution rule. The method of claim 2, The execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed, And the control means erases the execution rule in accordance with the mode setting information with reference to mode setting information included in the execution rule after executing the control according to the execution rule. The method of claim 3, The execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed, And the control means erases the execution rule in accordance with the mode setting information with reference to mode setting information included in the execution rule after executing the control according to the execution rule. The method of claim 4, wherein The execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed, And the control means erases the execution rule in accordance with the mode setting information with reference to mode setting information included in the execution rule after executing the control according to the execution rule. The method of claim 5, The execution rule includes mode setting information for setting whether or not to delete the execution rule from the execution rule storage means when the execution rule is executed, And the control means erases the execution rule in accordance with the mode setting information with reference to mode setting information included in the execution rule after executing the control according to the execution rule. The method of claim 1, The execution rule generated by the execution rule generating means specifies a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and an execution rule to be erased from the execution rule storage means when the condition is satisfied. A controller comprising information. The method of claim 2, The execution rule generated by the execution rule generating means specifies a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and an execution rule to be erased from the execution rule storage means when the condition is satisfied. A controller comprising information. The method of claim 3, The execution rule generated by the execution rule generating means specifies a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and an execution rule to be erased from the execution rule storage means when the condition is satisfied. A controller comprising information. The method of claim 4, wherein The execution rule generated by the execution rule generating means specifies a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and an execution rule to be erased from the execution rule storage means when the condition is satisfied. A controller comprising information. The method of claim 5, The execution rule generated by the execution rule generating means specifies a state variable of the monitoring destination device, a condition to be satisfied by the state variable, and an execution rule to be erased from the execution rule storage means when the condition is satisfied. A controller comprising information. At least, a program for imparting to a computer the function of each means of any one of claims 1 to 15. At least, a storage medium storing a program for imparting to a computer the function of each means of any one of claims 1 to 15.