JP2015087800A - Control program, apparatus control device, and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a method for starting dedicated application software for each load apparatus with a simple operation in easily operating a plurality of household load apparatuses by an information terminal device.SOLUTION: In a control program for causing an apparatus control device to control a plurality of load apparatuses, ID information of an apparatus selected from among the plurality of load apparatuses is obtained, a program having attribute information that corresponds to the ID information is extracted from among one or a plurality of other programs which are installed in the apparatus control device, and the other program(s) is executed.

Description

  The present invention relates to a home load device control program, device control apparatus, and control method using a network.

  2. Description of the Related Art In recent years, with the development of information technology, a technology for building a home network in a home and managing and controlling a plurality of load devices in one place has attracted attention. In particular, with increasing awareness of energy problems, there is an increasing need to install a power management device such as a HEMS (Home Energy Management System) to grasp the power consumption of devices at home (for example, Patent Document 1). ). In such a control system, there is a demand for a technology that can manage and control a plurality of load devices in the home using an information terminal device such as a smartphone that is rapidly spreading among individuals. .

JP 2010-128810 A

  By the way, when it is intended to control a plurality of load devices in the home by the information terminal device, it can be controlled by application software specialized for each load device provided by the manufacturer. However, dedicated application software must be started for each load device, and there is a problem that operation becomes complicated when control of a plurality of load devices is assumed.

In order to solve the above-described problems, a control program according to the present invention is:
A control program for causing a device control device to control a plurality of load devices,
Obtaining ID information of a device selected from the plurality of load devices;
A program having attribute information corresponding to the ID information is extracted from one or a plurality of other programs installed in the device control apparatus, and the other programs are executed.

  Further, the ID information is preferably information including at least one of information on a manufacturer of the selected device, a device type, and a device type.

  The information regarding the manufacturer of the selected device, the device type, and the device type is preferably a manufacturer code, a class code, and a product code defined in a predetermined communication protocol.

  The predetermined communication protocol is preferably ECHONET Lite.

  The attribute information is preferably information in a management database managed by the operating system of the device control apparatus.

  The attribute information is preferably a directory structure of the installed program.

  The attribute information is preferably header information provided in association with an execution file of the installed program.

  Moreover, it is preferable to display a new screen when application software having attribute information that matches the acquired ID information cannot be recognized, and to operate the selected load device in the new screen.

In order to solve the above-described problems, a control program according to the present invention is
A control program for causing a device control device to control a load device,
The ID information of the load device is stored as attribute information that can be read from another program.

  Further, the ID information is preferably information including at least one of information on a manufacturer of the load device, a type of the load device, and a type of the load device.

  The information regarding the manufacturer of the load device, the type of the load device, and the type of the load device is preferably a manufacturer code, a class code, and a product code defined in a predetermined communication protocol.

  The predetermined communication protocol is preferably ECHONET Lite.

  The attribute information is preferably information in a management database managed by the operating system of the device control apparatus.

  The attribute information preferably has a directory structure of the control program.

  The attribute information is preferably header information provided in association with an execution file of the control program.

In addition, in order to solve the above-described problems, the device control apparatus according to the present invention includes:
A device control device capable of controlling a plurality of load devices,
A display unit for displaying an operation object of the load device; and a control unit for performing display control of the operation object;
The control unit displays a selection object for selecting an arbitrary device from a plurality of load devices in the display unit by executing the first program,
The control unit acquires ID information of a device selected by the selection object, and executes a second program having attribute information corresponding to the acquired ID information.

In addition, in order to solve the above-described problems, a control method according to the present invention includes:
A control method by a device control device capable of controlling a plurality of load devices, the processing procedure by the device control device,
Displaying a selection object for selecting an arbitrary device from the plurality of load devices by executing the first program; and
A selection step of selecting an arbitrary device from the plurality of load devices;
An information acquisition step of acquiring ID information of the device selected by the selection step;
And a step of executing a second program having attribute information corresponding to the ID information acquired by the information acquisition step.

  ADVANTAGE OF THE INVENTION According to this invention, the complexity of operation of each apparatus at the time of having a some load apparatus in a household is eliminated, and a user's operativity and functionality can be made compatible.

The block diagram which shows the structure of the whole control system controlled by the apparatus control apparatus of this invention is shown. The block diagram which shows the structure of the apparatus control apparatus of this invention is shown. FIG. 3 shows a configuration diagram of a management database generated when a second program (apparatus application software) is installed in the first embodiment of the present invention. The main screen containing the load apparatus selection means and apparatus operation means displayed at the time of the 1st program (HEMS application software) execution of this invention is shown. The equipment detail screen of the 2nd program (apparatus application software) of this invention performed with selection of a load apparatus at the time of the 1st program (HEMS application software) execution of this invention is shown. It is a figure which shows the operation | movement flow of the whole control system containing the apparatus control apparatus of this invention in the 1st Embodiment of this invention. It is a figure which shows the correspondence of the kind of apparatus prescribed | regulated in ECHONET Lite specification, a class group code, and a class code. FIG. 10 shows a device detail screen displayed when there is no second program (device application software) of the present invention corresponding to a selected device when executing the first program (HEMS application software) of the present invention. In the second embodiment of the present invention, a configuration diagram of a directory generated when installing a second program (apparatus application software) is shown. In the 2nd Embodiment of this invention, it is a figure which shows the operation | movement flow of the whole control system containing the apparatus control apparatus of this invention. In the 3rd Embodiment of this invention, the block diagram of the program file produced | generated at the time of the 2nd program (apparatus application software) installation is shown. In the 3rd Embodiment of this invention, it is a figure which shows the operation | movement flow of the whole control system containing the apparatus control apparatus of this invention.

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

  The “essential command” in this specification refers to an essential command defined in accordance with the type of load device in a predetermined communication protocol. In the present embodiment, a case where ECHONET Lite is used as a communication protocol will be described. That is, in the following description, “essential command” refers to a command for accessing the “essential” property in each class specification corresponding to the load device in the ECHONET device object detailed specification, for example, “Release C”. In particular, “required command for air conditioner” in the description means “required” property in the home air conditioner class rule described in the same rule (specifies whether each setting (Set) or confirmation (Get) is mandatory) Points to the command to access

(First embodiment)
FIG. 1 is a block diagram showing a configuration of the entire control system 100 including the device control apparatus 3 of the present invention. The control system 100 operates the HEMS controller 1 responsible for controlling the entire system, the wireless LAN router 2 for connecting all the devices in the system via the wireless LAN, and the load device, and displays the device status. The apparatus control apparatus 3 for performing and various load apparatus 4a-4c, 5a-5c, 6-8 are provided.

  The HEMS controller 1 is network-connected by a wireless LAN between the device control apparatus 3 and various load devices 4a to 4c, 5a to 5c, and 6 to 8. As a protocol used for communication with each device, ECHONET Lite (registered trademark) certified as a HEMS standard protocol in Japan is used. The HEMS controller 1 transmits a command to each load device based on an operation from the device control device 3 to change the device state or acquire information on the current device state from each load device. The HEMS controller 1 is connected to a current sensor connected to the distribution board, and acquires power consumption information in the home. Further, the HEMS controller 1 acquires power consumption information of home appliances or the like from an outlet adapter such as a smart tap via a network. In the present embodiment, since the wireless LAN is used as the communication means, the communication is performed via the wireless LAN router 2.

  The device control apparatus 3 communicates with the load devices 4a to 4c, 5a to 5c, and 6 to 8 via the HEMS controller 1 or directly, and transmits a command for changing the operation state of the device. Get information about the current device status. The communication is also performed via the wireless LAN router 2.

  Specific examples of the device control device 3 include various devices such as a smartphone, a tablet PC (Personal Computer), a personal computer, and a television that can be connected to a network.

  Next, the hardware configuration of the device control apparatus 3 will be described. Here, description will be made assuming an information terminal device such as a smartphone as the device control device. In FIG. 2, the device control apparatus 3 inputs a control unit 21 that performs various control of the device, a storage unit 22 that stores various data, a transmission / reception unit 23 that transmits and receives radio waves, and an input to the device. An operation input unit 24 for performing an operation, a display unit 25 for performing screen display, a photographing unit 26 including a camera, a voice input unit 27 and a voice output unit 28 for voice input / output are provided.

  The control unit 21 includes a CPU (Central Processing Unit) 201 and performs various controls including execution of application software, encoding / decoding processing, and the like. The storage unit 22 records and reads various data including HEMS application software 202 (hereinafter, HEMS application 202) and device application software 203 (hereinafter, device application 203), which will be described later.

  The device control apparatus 3 is installed with a HEMS application 202 on the premise that the HEMS controller 1 is used in order to provide a user interface that is easy to use for the user. The user can access the device selection means and device operation means displayed on the screen of the HEMS application 202 by starting this software. The screen configuration of this software will be described in detail later.

  Furthermore, a device application 203 provided by a device manufacturer or the like for operation of each load device is installed in the device control apparatus 3. These software can usually be downloaded from the homepage of each device manufacturer or the like by the user. By using these software, it becomes possible to execute non-essential commands in addition to the essential commands defined in ECHONET Lite.

  FIG. 3 shows the internal structure of the management database (extracted only from the HEMS-related software part) managed by the operating system (OS). In the management database, management information is arranged in the form of a tree structure, and “device type” subkeys such as air conditioners and lighting are arranged under the HEMS subkey. Further, a “maker name” subkey is further arranged below the “device type” subkey.

  For example, after the user purchases the load device 4b (air conditioner manufactured by K company) and incorporates it into the HEMS control system 100 in the home, the user downloads the installer of the corresponding device application 203 from the homepage of the manufacturer, and the device control device Install in 3. The installer of the device application 203 has information on the type of the corresponding load device and the supplier, and generates a new subkey under a predetermined subkey in the management database based on the information when executing the installation. . That is, the installer of the device application 203 for the load device 4b has information that the type of the corresponding load device is “air conditioner” and the supply manufacturer is “K company”. Based on the information, an “air conditioner” subkey is generated in a hierarchy below the “HEMS” subkey in the management database, and a “company K” subkey is further generated in a hierarchy below it. This “Company K” subkey has folder information in which the device application 203 is installed as a value, and the OS can execute and start the device application 203 based on this information.

  Next, the load device will be described. The load devices 4a to 4c are air conditioners installed in the living room, Japanese-style room, and children's room, respectively. The load devices 4 a to 4 c have a built-in wireless LAN module or an external wireless LAN adapter, and are configured to be able to communicate with the HEMS controller 1 and the device control device 3 via the wireless LAN router 2. The same applies to the lighting, water heater, storage battery, and floor heating described below. The load devices 4a to 4c can receive and process the operation state ON / OFF setting / confirming command, the operation mode setting / confirming command, and the temperature setting value setting / confirming command as essential commands defined by ECHONET Lite. It is. These essential commands can be operated not only from the corresponding device application software but also from the HEMS application software as will be described later.

  The load devices 5a to 5c are lights installed in the living room, the Japanese-style room, and the child's room, respectively. The load devices 5a to 5c can receive and process an operation state ON / OFF setting / confirmation command and a lighting mode setting / confirmation command as essential commands defined by ECHONET Lite. These essential commands can be operated not only from the corresponding device application software but also from the HEMS application software. The same applies to the water heater, storage battery and floor heating described below.

  The load device 6 is a hot water heater. The load device 6 can receive and process an operation state ON / OFF confirmation command, a water heater combustion state confirmation command, and a bath water heater combustion state confirmation command as essential commands defined by ECHONET Lite.

  The load device 7 is a storage battery. The load device 7 can receive and process an operation state ON / OFF confirmation command, an operation mode setting / confirmation command, a remaining battery charge confirmation command, and a battery type confirmation command as essential commands defined by ECHONET Lite. is there. The storage battery used in this embodiment is a lithium ion battery, but other types of storage batteries such as nickel metal hydride batteries can also be used.

  The load device 8 is floor heating. The load device 8 can receive and process the operation state ON / OFF setting / confirmation command and the temperature setting value setting / confirmation command as essential commands defined by the ECHONET Lite.

  Next, the operation performed by the user on the device control device 3 will be specifically described. FIG. 4 shows the configuration of the main screen 400 that is first displayed when the HEMS application 202 is activated in the device control apparatus 3. In the following description, “button” refers to a “button object” displayed on the screen by a command from the control unit.

  The main screen 400 includes an INDEX unit 41 for classifying and displaying each type of load device, and a device display unit 42 for displaying selectable devices belonging to the device type selected in the INDEX unit 41. Is done. Further, in the device display unit 42, device selection buttons 43a to 43c for selecting each load device and device operation buttons 44a to 44c, 45a to 45c, 46a to operate each load device. 46c and device status display units 47a to 47c for displaying the status of each load device are arranged. FIG. 4 shows a display screen when “air conditioner” is selected as the device type in the INDEX unit 41.

  The device selection buttons 43a to 43c are arranged for individually selecting each load device belonging to the type of device selected in the INDEX unit 41. Immediately below each device operation button, “living room”, “Japanese room”, and “child's room”, which are installation locations of each device, are displayed.

  The device operation buttons 44a to 44c, 45a to 45c, 46a to 46c, and the device state display units 47a to 47c are respectively the operation state ON / OFF, operation mode, and temperature set value defined as the essential commands of the air conditioner in ECHONET Lite. A button and a display unit for performing setting (Set) and confirmation (Get). As described above, in the device display unit 42, only buttons and display units corresponding to commands defined as essential commands of the home air conditioner class in the ECHONET Lite are arranged without excess or deficiency. When the user selects illumination from the INDEX section, buttons for setting the operation state ON / OFF and lighting mode, which are defined as essential commands of the general illumination class, are arranged. The same applies to the case where a water heater, storage battery or floor heating is selected from the INDEX section.

  When the user wants to turn on the air conditioner arranged in the Japanese-style room, the user presses the device operation button 44b. Then, the air conditioner in the Japanese-style room starts to operate, and the display of the device status display section 47b on the screen is displayed as “status: ON”, “operation mode: dry”, “temperature set value: − ° C.”. When the user wants to change the operation mode, the operation mode displayed at the center of the device state display unit 47b is switched in the order of dry → air blowing → automatic → heating → dry by pressing the device operation button 45b.

  Next, it is assumed that the user wants to set the wind direction swing of the load device 4b (Japanese-style air conditioner). Since the wind direction swing setting is not an essential command defined by ECHONET Lite, the corresponding operation button is not displayed on the device display unit 42. Therefore, the user presses the device selection button 43b to display the device detail screen 500 of the device application 203 as shown in FIG. On the device detail screen 500, in addition to the buttons 52A, 52B, 53A to 53D, 54A, and 54B corresponding to the required command of the selected device type (air conditioner), the buttons 55A to 55C and 56A corresponding to the non-essential command are displayed. , 56B are displayed. Here, every time the user presses the device operation button 55C for setting the wind direction swing, the wind direction display (the direction of the black mark) in the device state display unit 51 changes in the order of OFF → up / down → left / right → up / down / left / right. .

  Next, specific operations of each device when the user operates the HEMS application 202 and the device application 203 will be described. FIG. 6 shows an operation flow of each device when the user executes the ECHONET Lite mandatory command and the non-essential command using the HEMS application 202 and the device application 203 in the first embodiment.

  The HEMS controller 1 is normally energized all day. In FIG. 6, when the HEMS controller 1 is first activated (S601), the device information is inquired to each of the load devices 4a to 4c, 5a to 5c, and 6 to 8 connected to the network (S602). Each load device on the network sends various information about the device to the HEMS controller 1, including manufacturer code, class group code and class code, product code, mandatory / non-essential commands supported by the device, and the latest device status. (S603). Based on the information obtained from each load device, the HEMS controller 1 creates an instance list in which each device is associated with the device information (S604). Further, even after activation, the HEMS controller 1 periodically collects various information from each load device, such as every other minute, and continuously updates the instance list.

  When the user activates the HEMS application 202 in the device control apparatus 3 (S605), the HEMS application 202 first requests an instance list in the HEMS controller 1 (S606). Based on the request from the HEMS application 202, the HEMS controller 1 transmits all or a part of the instance list managed by itself to the HEMS application 202 (S607). The instance list information transmitted to the HEMS application 202 includes the manufacturer code, class group code and class code of each load device, product code, required / non-essential command list to be supported, the latest device status of each load device, etc. It is.

  The HEMS application 202 performs display on the software screen based on the device status information of each load device acquired from the HEMS controller 1 (S608). For example, the HEMS application 202 displays the operation state, the operation mode, and the temperature setting value on the device state display units 47a to 47c in the device display unit 42 of FIG. 4 based on the device state of each air conditioner.

  Next, when the user presses the device operation button 44b to turn on the operation of the air conditioner (load device 4b) in the Japanese room (S609), the HEMS application 202 transmits a corresponding command to the load device 4b (S610). ). The load device 4b executes the command (operation ON) received from the HEMS application 202 in S610 (S611), and transmits the device status after execution to the HEMS application 202 (S612). When the HEMS application 202 receives the device status indicating that “operation is ON” via the HEMS controller 1, the display in the device status display unit 47 b displays “status: ON”, “operation mode: dry”, “temperature set value: − It changes to “° C.” (S613).

  Next, the user presses the device selection button 43b in order to perform the wind direction swing setting (non-essential command) of the load device 4b (S614). At this time, the HEMS application 202 has already acquired ID information such as the manufacturer code: 0x123456, the class group code: 0x01, and the class code: 0x30 of the load device 4b selected in S614 from the instance list in the HEMS controller 1. (S607). From the various codes acquired in S607 and the ECHONET Lite manufacturer code table and class code table (FIG. 7), the HEMS application 202 has the manufacturer of the load device 4b “K company” and the device type “air conditioner”. Recognize that.

  Next, the HEMS application 202 refers to the management database in FIG. 3 based on the recognition of the manufacturer and the device type (S615), and the “air conditioner” subkey in the “HEMS” subkey and “K company” in the hierarchy below it. The presence / absence of the sub key is confirmed (S616). When the corresponding subkey exists, the device application 203 is executed from the installation folder described in the “K company” subkey (S617).

  When the device application 203 is activated, a device detail screen 500 shown in FIG. 5 is displayed on the device control apparatus 3 (S618). Here, when the user presses the device operation button 55C for wind direction swing setting a predetermined number of times (S619), the device application 203 transmits a corresponding command to the load device 4b (S620). The load device 4b executes the command (wind direction swing setting: left and right) received from the device application 203 (S621), and transmits the device state after execution to the device application 203 (S622). Upon receiving the device state from the load device 4b, the device application 203 changes the wind direction display (the direction of the black mark) in the device state display unit 51 to “left and right” (S623).

  On the other hand, when the subkey representing the selected load device does not exist in the management database in S616, the device detail screen 800 for detailed operation is displayed in the same HEMS application 202 as shown in FIG. (S624). Here, the user presses the device operation button 87C a predetermined number of times in order to perform wind direction swing setting, which is a non-essential command (S625). Then, the HEMS application 202 transmits a corresponding command to the load device 4b (S626). The load device 4b executes the command (wind direction swing setting: left and right) received from the HEMS application 202 in S626 (S627), and transmits the device state after execution to the HEMS application 202 (S628). When receiving the device state via the HEMS controller 1, the HEMS application 202 changes the wind direction display (the direction of the black mark) in the device state display unit 83 to “left and right” (S629).

  In the present embodiment, the HEMS application 202 acquires a manufacturer code, a product code, a mandatory / non-essential command supported by the device from the instance list in the HEMS controller 1, and the latest device state of the load device from each load device. Although it has been configured to acquire via the HEMS controller 1, the present invention is not limited to this form. The HEMS application 202 may acquire all the above information directly from each load device, or may acquire all the above information from the HEMS controller 1.

  Further, in the present embodiment, the screen for displaying the essential command in the HEMS application 202 is classified according to the type of device and displayed in INDEX, but the present invention is not limited to this form. It is possible to customize the apparatus appropriately so that the user classifies the apparatus for each room and displays the INDEX.

  In the present embodiment, the HEMS controller 1 acquires ID information for identifying a device from each load device in S603, and the HEMS application 202 obtains information for identifying the device from the HEMS controller 1 in S607. However, the present invention is not limited to this. The HEMS application 202 may be configured to directly obtain information for specifying a device from each load device.

  In the present embodiment, the control system 100 is configured to connect all devices in the system to the network via a wireless LAN, but the present invention is not limited to this mode. For example, the control system 100 may be network-connected by another standard communication protocol in which a physical layer is defined, such as ETHERNET (registered trademark) or PLC (Power Line Communication).

  In the present embodiment, the control system 100 uses ECHONET Lite as a communication protocol when communicating with each device and operates in combination with a wireless LAN. However, the present invention is not limited to this mode. For example, the control system 100 communicates with other wireless communication protocols such as ZigBee (registered trademark) SEP 2.0 (Smart Energy Profile 2.0) in combination with a wireless LAN or the like, which provides a degree of freedom in the physical layer and defines only the upper layer. You may do.

  Moreover, in this embodiment, although the apparatus control apparatus 3 was connected with HEMS controller 1 and each load apparatus via wireless LAN, this invention is not limited to this form. The HEMS controller 1 may be connected to the Internet, and similarly, each load device may be controlled via the HEMS controller 1 from a device control device 3 that is connected to the Internet.

  Further, in this embodiment, when searching for a device application corresponding to the selected load device, it is configured to check whether the manufacturer and the type of device match, but the present invention has this configuration. It is not limited. Software to be executed may be selected from various other information that can identify the load device.

  In particular, in this embodiment, the HEMS application 202 compares the manufacturer code, class group code, and class code acquired from the HEMS controller 1 with the “device type name” subkey and “manufacturer name” subkey in the management database. Although the apparatus application to be executed is specified, the present invention is not limited to this form. The manufacturer code and the product code may be configured to be compared with the “manufacturer name” subkey and the “product name” subkey. If the device can be identified only from the product code, the product code and the “product name” subkey You may comprise so that only may be compared. Further, the management database may be configured using the manufacturer code acquired by the HEMS application 202 from the HEMS controller 1 as a subkey name as it is.

  In the present embodiment, for the sake of clarity, the operation means provided on the device application 203 in FIG. 5 and the operation means provided on the device details screen of the HEMS application 202 in FIG. 8 are substantially the same. . However, in reality, the device application provided by each device manufacturer can provide a user interface with excellent operability according to the characteristics of each device, rather than the device details screen of the HEMS application. Therefore, it is considered that the improvement effect of functionality by enabling the device application to be linked and activated from the HEMS application is greater than that of the present embodiment.

(Second Embodiment)
In the second embodiment of the present invention, instead of the management database of FIG. 3 in the first embodiment, the device application 203 is activated in cooperation using a directory structure as shown in FIG. This is the same as in the first embodiment. Therefore, in the following description of the second embodiment, a description will be given specifically for the installation scene of the device application 203 and the scene in which the device application 203 is activated in cooperation from the HEMS application 202.

  The user purchases the load device 4b (air conditioner manufactured by K company), incorporates it into the HEMS control system 100 in the home, and then downloads the installer of the corresponding device application 203 from the homepage of the supplier and downloads it in the device control device 3 To install. The installer of the device application 203 has information on the type of the corresponding load device and the supplier, and generates an installation directory based on the information when executing the installation. That is, the installer of the device application 203 for the load device 4b has information that the corresponding load device type is “air conditioner” and the supply manufacturer is “K company”. Based on the information, a “air conditioner” directory is generated in a predetermined application installation directory, and a directory “company K” is generated in a lower hierarchy. As will be described later, when the device selection button is pressed in the HEMS application 202, the HEMS application 202 uses the information on the manufacturer of the selected load device and the type of device acquired via the HEMS controller 1 to Specify the installation directory. Then, the executable file in the specified directory is executed to start the application.

  FIG. 10 shows an operation flow of the control system 100 when a user executes an ECHONET Lite mandatory command and a non-essential command using the HEMS application 202 and the device application 203 in the second embodiment of the present invention.

  In the main screen of the HEMS application 202 of FIG. 4, it is assumed that the user presses the device selection button 43b in order to set the wind direction swing (non-essential command) of the load device 4b (S1014). At this time, the HEMS application 202 has already acquired ID information such as the manufacturer code: 0x123456, the class group code: 0x01, and the class code: 0x30 of the load device 4b from the instance list in the HEMS controller 1 (S1007). From the various codes acquired in S1007 and the manufacturer code table and class code table (FIG. 7) of ECHONET Lite, the HEMS application 202 has the manufacturer of the load device 4b as “Company K” and the device type as “air conditioner”. Recognize that.

  Next, the HEMS application 202 refers to the installation directory of FIG. 9 based on the recognition of the manufacturer and the device type (S1015), and the “air conditioner” directory in the “HEMS” directory and “K company” in the hierarchy below it. The presence / absence of the directory is confirmed (S1016). When the corresponding directory exists, the application execution file in the “K company” directory is executed (S1017), and the device application 203 is activated and displayed (S1018). Each operation after activation of the device application 203 is the same as in the first embodiment.

  On the other hand, when the directory of the selected load device does not exist in the installation directory in S1016, a device detail screen 800 for detailed operation is displayed in the same HEMS application 202 as shown in FIG. (S1024). Each operation after the device detail screen 800 is displayed is the same as in the first embodiment.

  In this embodiment, the manufacturer code, class group code, and class code acquired by the HEMS application 202 from the HEMS controller 1 are compared with the “device type name” directory and the “maker name” directory in a predetermined installation directory. Although the apparatus application to be executed is specified, the present invention is not limited to this form. The manufacturer code and the product code may be configured to be compared with the “manufacturer name” directory and the “product name” directory. If the device can be specified only from the product code, the product code and the “product name” directory may be used. You may comprise so that only may be compared. Further, the installation directory may be configured by using the manufacturer code obtained by the HEMS application 202 from the HEMS controller 1 as a directory name as it is.

(Third embodiment)
In the third embodiment of the present invention, the device application 203 is activated in cooperation using header information in the program file 1100 as shown in FIG. 11 instead of the management database in FIG. 3 in the first embodiment. . Therefore, in the following description of the third embodiment, a description will be given specifically for the installation scene of the device application 203 and the scene in which the device application 203 is activated in cooperation from the HEMS application 202.

  The user purchases the load device 4b (air conditioner manufactured by K company), incorporates it into the HEMS control system 100 in the home, and then downloads the installer of the corresponding device application 203 from the homepage of the supplier and downloads it in the device control device 3 To install. In the present embodiment, the program file 1100 of the device application 203 generated at the time of installation is stored in a predetermined installation directory. Each program file 1100 has a data structure as shown in FIG. That is, each program file 1100 has a header information section 1101 in a text format located at the head portion thereof, and an executable file section 1102 in a binary format subsequent thereto. The header information part 1101 includes a manufacturer code, a class group code, a class code, and a product code of a load device supported by the device application. That is, the header information part 1101 of the device application 203 of the load device 4b includes a manufacturer code: 0x123456, a class group code: 0x01, a class code: 0x30, and a product code: Kair01.

  FIG. 12 shows an overall operation flow of the control system 100 when a user executes an ECHONET Lite mandatory command and a non-essential command using the HEMS application 202 and the device application 203 in the third embodiment of the present invention.

  In the main screen of the HEMS application 202 of FIG. 4, it is assumed that the user presses the device selection button 43b in order to set the wind direction swing (non-essential command) of the load device 4b (S1214). At this time, the HEMS application 202 has already acquired ID information such as the manufacturer code: 0x123456, the class group code: 0x01, and the class code: 0x30 of the load device 4b selected in S1214 from the instance list in the HEMS controller 1. (S1207). The HEMS application 202 refers to the manufacturer code, the class group code, and the class code described in the header information part 1101 of each program file 1100 installed in a predetermined directory (S1215), and each code acquired in S1207 Are compared (S1216). If there is a program file 1100 having header information corresponding to the information acquired in S1207, the execution file portion 1102 in the program file is executed (S1217), and the device application 203 is activated and displayed (S1218). Each operation after activation of the device application 203 is the same as in the first and second embodiments.

  On the other hand, when the program file 1100 having the header information corresponding to the information acquired in S1207 does not exist in S1216, as shown in FIG. 8, the device details screen 800 for detailed operation in the same HEMS application 202 is shown. Is displayed (S1224). Each operation after the device detail screen 800 is displayed is the same as in the first and second embodiments.

  In the present embodiment, the HEMS application 202 is configured to identify the device application to be executed by comparing the manufacturer code, class group code, and class code acquired from the HEMS controller 1 with the code in the header information. It is not limited to this form. The manufacturer code and the product code may be compared with the header information. If the device can be identified only from the product code, the product code may be compared with the header information.

  In the present embodiment, a header information part and an execution file part are provided in the program file, and the manufacturer code and the like are stored as attribute information of the program in the header information part. However, the present invention is not limited to this form. Another file or the like having an extension different from that of the executable file may be created in the same directory, and the attribute information may be described in the separate file.

  In the present embodiment, the data in the header information section is text format data, but the present invention is not limited to this format, and may be binary format data.

  As described above, according to the embodiment of the present invention, the ID information of the selected load device is acquired, and the application to be executed is determined and executed by comparing with the attribute information of the installed device application. Therefore, the user can easily access non-essential operation means.

  In addition, according to the embodiment of the present invention, the device application can be linked and activated using the manufacturer code, the class code, and the product code defined in ECHONET Lite as the ID information of the selected load device. It is possible to construct a highly reliable system.

  In addition, according to the embodiment of the present invention, when there is no device application corresponding to the selected load device, it is possible to operate a non-essential command on a separate screen in the HEMS application, so that a stable function can be provided to the user. It becomes possible to provide sex.

  In addition, according to the embodiment of the present invention, since it is configured to have the ID information of the load device to be operated as the attribute information of the device application, the device according to the user's request from the highly versatile HEMS application. It becomes easy to start linked applications.

  Although the present invention has been described based on the drawings and examples, it should be noted that those skilled in the art can easily make various changes or modifications based on the present disclosure. Therefore, it should be noted that these variations or modifications are included in the scope of the present invention. For example, the functions included in each member, each means, each step, etc. can be rearranged so as not to be logically contradictory, and a plurality of means, steps, etc. can be combined into one or divided. Is possible.

DESCRIPTION OF SYMBOLS 1 HEMS controller 2 Wireless LAN router 3 Apparatus control apparatus 4a-4c Load apparatus (air conditioner)
5a-5c Load equipment (lighting)
6 Loaded equipment (water heater)
7 Load equipment (storage battery)
8 Loaded equipment (floor heating)
DESCRIPTION OF SYMBOLS 21 Control part 22 Memory | storage part 23 Transmission / reception part 24 Operation input part 25 Display part 26 Image | photographing part 27 Audio | voice input part 28 Audio | voice output part 41 INDEX part 42 Equipment display part 43a-43c Equipment selection button 44a-44c Equipment operation button 45a-45c Equipment Operation buttons 46a to 46c Device operation buttons 47a to 47c Device state display unit 51 Device state display unit 52A to 52B Device operation buttons 53A to 53D Device operation buttons 54A to 54B Device operation buttons 55A to 55C Device operation buttons 56A to 56B Device operation buttons 81 INDEX section 82 device detail display section 83 device status display section 84A-84B device operation button 85A-85D device operation button 86A-86B device operation button 87A-87C device operation button 88A-88B device operation button 89 main screen button Down 100 control system 201 CPU
202 HEMS application software 203 Device application software 400 Main screen 500 Device details screen 800 Device details screen 1100 Program file 1101 Header information part 1102 Execution file part

Claims (17)

A control program for causing a device control device to control a plurality of load devices,
Obtaining ID information of a device selected from the plurality of load devices;
A control program that extracts a program having attribute information corresponding to the ID information from one or more other programs installed in the device control apparatus and causes the other program to be executed.   The control program according to claim 1, wherein the ID information is information including at least one of information related to a manufacturer of the selected device, a device type, and a device type.   The control program according to claim 2, wherein the information regarding the selected device manufacturer, device type, and device type is a manufacturer code, a class code, and a product code defined in a predetermined communication protocol, respectively.   The control program according to claim 3, wherein the predetermined communication protocol is ECHONET Lite.   The control program according to any one of claims 1 to 4, wherein the attribute information is information in a management database managed by an operating system of the device control apparatus.   The control program according to any one of claims 1 to 4, wherein the attribute information is a directory structure of the installed program.   The control program according to any one of claims 1 to 4, wherein the attribute information is header information provided in association with an execution file of the installed program.   8. A new screen is displayed when application software having attribute information that matches the acquired ID information cannot be recognized, and the selected load device is operated in the new screen. The control program according to any one of the above. A control program for causing a device control device to control a load device,
A control program that holds ID information of the load device as attribute information that can be read from another program.   The control program according to claim 9, wherein the ID information is information including at least one of information on a manufacturer of the load device, a type of the load device, and a type of the load device.   The control program according to claim 10, wherein the information on the manufacturer of the load device, the type of the load device, and the type of the load device is a manufacturer code, a class code, and a product code defined in a predetermined communication protocol.   The control program according to claim 11, wherein the predetermined communication protocol is ECHONET Lite.   The control program according to any one of claims 9 to 12, wherein the attribute information is information in a management database managed by an operating system of the device control apparatus.   The control program according to any one of claims 9 to 12, wherein the attribute information is a directory structure of the control program.   The control program according to any one of claims 9 to 12, wherein the attribute information is header information provided in association with an execution file of the control program. A device control device capable of controlling a plurality of load devices,
A display unit for displaying an operation object of the load device; and a control unit for performing display control of the operation object;
The control unit displays a selection object for selecting an arbitrary device from a plurality of load devices in the display unit by executing the first program,
The control unit is configured to acquire ID information of a device selected by the selection object, and to execute a second program having attribute information corresponding to the acquired ID information. A control method by a device control device capable of controlling a plurality of load devices, the processing procedure by the device control device,
Displaying a selection object for selecting an arbitrary device from the plurality of load devices by executing the first program; and
A selection step of selecting an arbitrary device from the plurality of load devices;
An information acquisition step of acquiring ID information of the device selected by the selection step;
And a step of executing a second program having attribute information corresponding to the ID information acquired by the information acquisition step.

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