JP2010263536A - Home electric appliance control system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a home electric appliance control system in which a remote control code for each maker of home electric appliance products is acquired and a device is enabled to perform user desired operation in transmitting a combination of minimum remote control codes. <P>SOLUTION: A user uses a TV remote controller to select desired air conditioner control from among control contents relating to an air conditioner that is one of infrared control devices displayed on the TV. A control signal selecting the control content is transmitted from the TV remote controller to the TV by radio and transmitted from the TV to an administrative server over the Internet. The administrative server generates a remote control code required for control on the basis of the selected control contents and state data, recorded inside, of the device to be controlled. The remote control code generated is sequentially transmitted from the administrative server to the TV over the Internet and transmitted from the TV to the TV remote controller. The TV remote controller converts the remote control code received into an infrared signal and transmits the infrared signal to the air conditioner. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

The present invention relates to a home appliance operation system that remotely controls a plurality of home appliances with a single remote controller (remote controller).

Conventionally, a remote controller using infrared rays has been widely used as a user interface for remotely controlling home appliances. In general, a remote control is required for each home appliance. Therefore, there are a plurality of remote controllers for a plurality of home appliances that are operated by an infrared remote controller in the home. Users are forced to use the remote control for each home appliance.

  In order to solve such inconvenience, a multi-remote controller that can deal with a plurality of home appliances with one remote controller is commercially available.

  When a terminal that can be connected to a network such as the Internet downloads a remote control code for each device manufacturer and sends a command corresponding to the remote control code, the transceiver (remote control station) that received the command A remote control system configured to transmit to a device and remotely control a desired device has been proposed (for example, Patent Document 1).

JP 2007-116484 A

However, the multi-remote control has an operation interface (buttons, etc.) for compatible home appliances, and the remote control code of the manufacturer selected by the user from the corresponding manufacturer group is read and transmitted according to the interface operation. Due to the mechanism, there is a problem that the types of manufacturers and home appliances that can be controlled in advance are limited.

  In the system disclosed in Patent Document 1 described above, the commands that can be operated are limited to operations using a single command corresponding to the remote control code for each manufacturer. A send operation needs to be performed.

  The home appliance operating system according to the first aspect of the invention is a management server, a television receiver (hereinafter referred to as TV) connected to the management server and a network interface (hereinafter referred to as I / F), and a TV and a wireless I / F. The management server consists of a remote controller that can be connected, and the management server records the current control state of the device currently controlled by the management server, and the remote control code that records the operation of the device and the remote control code data Based on the user's desired control represented by a combination of the operation of the device recorded in the storage unit and the remote control code storage unit and the remote control code included in the remote control code data, A remote control for reading out a remote control code necessary for realizing a desired control state from the remote control code storage unit A code generation unit, and a control unit that transmits the generated remote control code via the network I / F. The terminal includes a control unit that transmits the remote control code received via the network I / F via the wireless I / F. A control unit that sends the remote control code received by the wireless I / F to the signal conversion unit, a signal conversion unit that converts the remote control code into an infrared signal, and an infrared transmission / reception unit are provided.

  In the management server of the home appliance operation system according to the present invention, the difference between the user-desired control content sent via the network I / F and the device status recorded in the status storage unit is derived for each type of control. A list of remote control codes necessary for realizing the control can be generated.

  Also, the generated remote control code is sent to the TV via the network I / F, the remote control code received from the management server is sent to the TV remote control via the wireless I / F, and received from the TV via the wireless I / F. The remote control code is converted into an infrared signal by the TV remote controller and sent to the device by the TV remote controller, so that the remote control code in the remote control code list generated by the management server can be sent to the device.

  In this way, the control by the combination of remote control codes is presented to the user, and the selected control can be realized by transmitting the minimum number of remote control codes, so that the user selectable control without proportionally increasing the number of remote control code transmissions It is feasible to increase

  The home appliance operation system according to the second invention is the configuration of the home appliance operation system according to the first invention, in which the state storage unit of the management server includes the device state (state / time at the time of final operation, total use time / power consumption, Period of use), current control state, and control time, and the management server controls the current device from the image data storage unit that stores image data related to the device, and the state storage unit and the image data storage unit. A display unit that includes a control screen generation unit that generates display screen data reflecting a state, and a control unit that transmits the display screen data through a network I / F. The TV displays display screen data received through the network I / F. It is characterized by providing.

  In the home appliance operation system according to the present invention, the device state recorded in the state storage unit and the image data relating to the device are used to indicate the current device control state, and the power consumption and the number of times of use are determined from the device state in the state storage unit. Information such as frequency can be created and display screen data shown to the user can be created.

  According to a third aspect of the present invention, there is provided a home appliance operating system in the configuration of the home appliance operating system according to the first and second inventions, wherein the management server is a device operation and remote controller for a plurality of infrared operating devices managed in the home. A control device group data section that records code data, device status, and device-related image data, and controls loading of data into the remote control code storage unit, status storage unit, and image data storage unit based on user device selection Features a part.

  In the home appliance operation system according to the present invention, a remote control code set and a device state of a plurality of home appliances are recorded in the management device group data unit, and image data related to the device is recorded. Data can be loaded into the state storage unit and the image data storage unit, and the first and second devices can be controlled and displayed.

  The home appliance operation system of the present invention presents control in a combination of remote control codes and, based on the current state of the device, transmits only the minimum necessary remote control code from the desired combination to the device and proportionally increases the number of remote control code transmissions. Since it does not increase, it is possible to increase the user-selectable control.

  In addition, the home appliance operation system of the present invention records the state of the device based on the transmitted remote control code, and can create information such as power consumption, number of uses, and frequency, so that the user can grasp the state of the device.

  In addition, the home appliance operation system of the present invention stores a remote control code, device status, and image data for controlling a plurality of devices in the server, and various controls can be performed by selecting a user desired device from there. Therefore, it is possible to realize home appliance operation that does not limit the types of manufacturers and home appliances.

Overall system configuration diagram in Embodiment 1 of the present invention System configuration diagram according to the first embodiment of the present invention Control transmission processing flowchart of the TV remote controller in Embodiment 1 of the present invention Control transmission processing flowchart of TV in Embodiment 1 of the present invention Processing flowchart of the management server 6 in Embodiment 1 of the present invention TV control reception processing flowchart according to the first embodiment of the present invention. TV remote control control reception processing flowchart according to the first embodiment of the present invention. Control screen diagram of Company A air conditioner in Embodiment 1 of the present invention Screen for control after state transition of Company A air conditioner in Embodiment 1 of the present invention FIG. 4 is a diagram of an example of a remote control code list for the air conditioner A according to the first embodiment of the present invention. The figure of the remote control cord set of A company air conditioner in Example 1 of the present invention Control screen diagram of Company B air conditioner in Embodiment 1 of the present invention FIG. 6 is a diagram of an example of a remote control code list for the air conditioner B according to the first embodiment of the present invention. FIG. 3 is a diagram of a remote control cord set for a B company air conditioner in Embodiment 1 of the present invention

  Hereinafter, the best mode for carrying out the invention will be described with reference to the drawings.

Example 1
FIG. 1 is an overall system configuration diagram related to the user IF of the present invention. A configuration of a home appliance state management system using a wireless / infrared remote controller will be described. The home appliance state management system includes an audio player 1, an air conditioner 2, an infrared operation device such as a video recorder 3, a TV remote control 4, a TV 5, a management server 6, a company A home appliance information server 7, a company B home appliance information server 8, and the like. Consists of information servers for each manufacturer.

  Audio player 1, air conditioner 2, video recorder 3 and TV remote controller 4 are connected by infrared rays. The TV remote controller 4 and the TV 5 are connected wirelessly. The TV 5 and the management server 6 are connected via the Internet network. The management server 6, the A company home appliance information server 7, and the B company home appliance information server 8 are connected via the Internet. The Audio player 1, the air conditioner 2, and the video recorder 3 are infrared operating devices in the home.

  The management server 6 is a server that manages the operation state and remote control code of the infrared operation device in the home and controls the infrared operation device in the home via the TV 5 and the TV remote control 4. The A company home appliance information server 7 and the B company home appliance information server 8 are servers managed by the manufacturer of the infrared operation device. The basics such as the remote control code group of the infrared operation device, the power consumption of the device, and the production date A server that holds information.

  An infrared operating device such as the audio player 1, the air conditioner 2, and the video recorder 3 and the TV remote controller 4 communicate with each other by infrared rays. A device identification number is transmitted to the TV remote controller 4 from the infrared operation device. The device identification number is a numeric string that can uniquely identify the model name of the manufacturer of the infrared operating device. A remote control code is transmitted from the TV remote controller 4 to the infrared device.

  The TV remote controller 4 and the TV 5 communicate wirelessly. An operation signal and the device identification number are transmitted from the TV remote controller 4 to the TV 5. A remote control code is transmitted from the TV 5 to the TV remote controller 4.

  The TV 5 and the management server 6 communicate via the Internet network. An operation signal from the TV remote controller 4 and the device identification number are transmitted from the TV 5 to the management server 6. Display screen data to be displayed on the TV 5 and a remote control code are transmitted from the management server 6 to the TV 5. The management server 6, the A company home appliance information server 7 and the B company home appliance information server 8 and other information servers for each manufacturer communicate via the Internet. From the information server for each manufacturer, a set of remote control codes of the infrared operating device manufactured by the manufacturer and basic information are transmitted to the management server 6.

  Next, taking the air conditioner 2 from the infrared operating device as an example, the system configuration diagram of the air conditioner 2, the TV remote controller 4, the TV 5, and the management server 6 will be described in more detail with reference to FIG. FIG. 2 is a system configuration diagram including the management server 6, the TV 5, the TV remote controller 4, and the air conditioner 2 in the overall system configuration diagram.

  The management server 6 includes a management device group data unit 60, a remote control code storage unit 61, a status storage unit 62, an image data storage unit 63, a remote control code list generation unit 64, a control screen generation unit 65, a control unit 66, a network I / O Consists of F67. The hardware of the management server 6 includes an HDD 70 that is a nonvolatile external storage device, a memory 71 that is a volatile external storage unit, a CPU 72, and a network I / F 67. The HDD 70 and the memory 71 are connected by a data bus. The HDD 70 and the CPU 72 are connected by an external bus. The memory 71 and the CPU 72 are connected by a bus. The CPU 72 and the network I / F 67 are connected by a bus.

  The management device group data section 60 is a partial storage area of the HDD 70 and records data of a plurality of infrared operation devices managed in the home. Managed device group data refers to the remote control code set of each device (device operation and remote control code set data), device status (status / time at the time of final operation, total usage time / power consumption, usage period), and images related to the device It is data.

  The remote control code storage unit 61 is a partial storage area of the memory 71 and stores data of the remote control code set of the device currently controlled by the management server 6. The state storage unit 62 is a partial storage area of the memory 71 and stores the device state data, the current control state, and the control time regarding the device currently controlled by the management server 6.

  The image data storage unit 63 is a partial storage area of the memory 71 and stores image data related to the device currently controlled by the management server 6 and operation screen image data for user operation. The remote control code list generation unit 64 is a program that operates in the CPU 72, and generates a remote control code list that is a set of control and remote control codes necessary for transition from the current state based on a control list indicating after the state transition of the device. To do.

  The control screen generation unit 65 is a program that operates in the CPU 72, and generates display screen data reflecting the current control state of the device based on a screen change instruction. The control unit 66 is a program that operates in the CPU 72, and controls update of data in the remote control code storage unit 61, status storage unit 62, and image data storage unit 63, transmission / reception control of the network I / F, and remote control code list generation unit 64. The remote control code list generation instruction control to the control screen and the display screen data generation instruction control to the control screen generation unit 65 are performed.

  The control unit 66 receives a device identification number or a control signal from the TV 5 via the network I / F 67. The control list is transmitted to the remote control code list generation unit 64. The remote control code list is received from the remote control code list generation unit 64. The remote control code in the remote control code list is transmitted to the TV 5 via the network I / F 67. The status change of the device by the transmitted remote control code list is recorded in the status storage unit 62. A screen change instruction is transmitted to the control screen generation unit 65. The display screen data is received from the control screen generator 65 and transmitted to the TV 5 via the network I / F 67.

  The remote control code list generation unit 64 receives the control list from the control unit 66. The device status data is read from the status storage unit 62. The remote control code is read from the remote control code storage unit 61. The remote control code list is transmitted to the control unit 66. The control screen generator 65 receives a screen change instruction signal from the controller 66. Read state data from the state storage. Image data is read from the image data storage unit 63. The generated display screen data is transmitted to the control unit 66.

  The TV 5 includes a network I / F 50, a control unit 51, a display unit 52, and a wireless I / F 53. The network I / F 50 and the control unit 51 are connected by a bus. The control unit 51 and the display unit 52 are connected by a bus. The control unit 51 and the wireless I / F 53 are connected by a bus. The control unit 51 is a microcomputer that controls display change of the display unit 52 and data transmission / reception of the network I / F 50 and the wireless I / F 53.

  The display unit 52 is a display device that is controlled by the control unit 51 and displays screen data. The control unit 51 transmits the remote control code received from the network I / F 50 from the management device server 6 to the TV remote control 4 using the wireless I / F 53. The display of the display unit 52 is updated with the display screen data from the management device server 6 received by the network I / F 50.

  Based on the operation signal received by the wireless I / F 53, the display of the display unit 52 is updated. Alternatively, the operation signal is transmitted as a control signal to the management device server 6 through the network I / F 50. The device identification number received by the wireless I / F 53 is transmitted to the management device server 6 by the network I / F.

  The TV remote controller 4 includes an input unit 41, a control unit 42, a wireless I / F 43, a signal conversion unit 44, and an infrared transmission / reception unit 45. The input unit 41 and the control unit 42 are connected by a data bus. The control unit 42 and the signal conversion unit 44 are connected by a bus. The signal conversion unit 44 and the wireless I / F 43 are connected by a bus.

  The input unit 41 is a device that receives user operations. A typical example of a device for receiving an operation is a button or a sensor. The control unit 42 is a microcomputer that performs data transmission / reception control with the wireless I / F 43, the signal conversion unit 44, and reception control from the input unit 41. The signal conversion unit 44 is a conversion device that converts between a signal and an infrared signal. The input unit 41 transmits a signal based on a user operation to the control unit 42.

  The control unit 42 transmits the signal received from the input unit 41 as an operation signal to the TV 5 through the wireless I / F 43. The remote control code received from the TV 5 by the wireless I / F 43 is transmitted to the signal conversion unit 44. The signal received from the signal conversion unit 44 is transmitted to the TV 5 by the wireless I / F 43. The signal conversion unit 44 converts the signal received from the control unit 42 into an infrared signal, and transmits the infrared signal to the air conditioner 2 by the infrared transmission / reception unit 45. The infrared signal from the air conditioner 2 received by the infrared transmission / reception unit 45 is converted and transmitted to the control unit 42.

  The air conditioner 2 includes an infrared transmission / reception unit 21 and a device identification number storage unit 22. The infrared transmission / reception unit 21 and the device identification number storage unit 22 are connected by a bus. The infrared transmitter / receiver 21 receives the remote control code from the TV remote controller 4. The air conditioner 2 operates in accordance with the remote control code. The device identification number read from the device identification number storage unit 22 is transmitted to the TV remote controller 4 by the infrared transmission / reception unit 21.

  Next, the control and operation of the user IF of the present invention will be described with reference to FIGS. FIG. 3 is a flowchart showing the transmission operation of the TV remote controller 4 to the TV 5. FIG. 4 is a flowchart showing the transmission operation of the TV 5 to the management server 6. FIG. 5 is a flowchart showing the operation of the management server 6. FIG. 6 is a flowchart showing the reception operation of the TV 5 from the management server 6. FIG. 7 is a flowchart showing the reception operation of the TV remote controller 4 from the TV 5.

  First, the device identification number of the air conditioner 2 is sent to the management server 6 via the TV remote controller 4 and the TV 5, so that the data related to the air conditioner 2 is transferred from the management device group data unit 60 to the remote control code storage unit 61, status in the management server 6. A device to be controlled is selected so as to be loaded into the storage unit 62 and the image data storage unit 63, and a device control screen is created by the management server 6, sent to the TV 5, and displayed on the display unit 52 of the TV 5 in FIG. The control until it is shown to the user will be described with reference to FIGS.

  The processing flow of FIG. 3 starts when the TV remote controller 4 receives the device identification number from the air conditioner 2. When the operation signal is not received from the input unit 41 (step S301) and the infrared signal is received by the infrared transmission / reception unit 45 (step S303), the signal conversion unit 44 enters the infrared signal in the device identification No. in step S304. Convert to signal. Thereafter, the process proceeds to step S305, where the device identification No. signal is transmitted to the TV 5 by the wireless I / F 43, and the process ends.

  The processing flow in FIG. 4 starts when the TV 5 receives the device identification number from the TV remote controller 4 through the wireless I / F 53. When the device identification number is received by the wireless I / F 53 (step S401), the process enters step S402, the device identification number is transmitted to the management server 6 by the network I / F 50, and the process ends.

  The processing flow of FIG. 5 starts when the management server 6 receives the device identification number from the TV 5 at the network I / F 67. When the device identification number is received by the network I / F 67 (step S501), the process enters step S502. In step S502, the control unit 66 of the management server 6 loads the remote control code set and the image data from the management device group data unit 60 to the remote control code storage unit 61 and the image data storage unit 63 based on the device identification No. Overwrite the data related to the connected device. The status data is read from the status storage unit 62, and the status data of the currently controlled device in the managed device group data unit 60 is updated. The state data in the management device group data unit 60 based on the device identification number is overwritten on the state data in the state storage unit 62.

  In step S503, the control unit 66 transmits a screen change instruction to the control screen generation unit 65. The control screen generation unit 65 reads data from the image data storage unit 63 based on the state data read from the state storage unit 62, generates display screen data for the device control screen, and transmits the display screen data to the control unit 66. The control unit 66 transmits the display screen data to the TV 5 via the network I / F 67, and the process ends.

  The processing flow of FIG. 6 starts when the TV 5 receives the display screen data from the management server 6 via the network I / F 67. When the display screen data is received by the network I / F 67 (step S601), the process proceeds to step S603, where the control unit 51 changes the display of the display unit 52 with the received display screen data and ends.

In addition to the control described above, the following two controls can be used for determining the device to be controlled. As the first control, a list of devices to be controlled is displayed on the TV 5, and the device to be controlled is determined by causing the user to select the input unit 41 of the TV remote controller 4. As the second control, the management device server 6 transmits a remote control code indicating the power ON of the control target device in the home managed by the management server 6 to the control device air conditioner 2 that the user wants to select. Are sequentially transmitted via the TV remote controller 4, and when the power of the air conditioner 2 is turned on, the user transmits a determination operation signal at the input unit 41 of the TV remote controller 4 to determine a device to be controlled. In the case of the first control, the management server 6 in step S501 receives the device identification number from the TV 5 through the network I / F 67, and enters the flow in S502. The flow changes to S502 upon reception of the signal. The management server 6 determines a control target device based on the operation signal for selecting the device, and loads data of the control target device from the management device group data unit 60 in step S502.

  On the other hand, in the case of the second control, in the flowchart shown in FIG. 5, the management server 6 sequentially transmits a remote control code indicating the power ON of each device of the management device group data in the management device group data section 60 to the TV 5. Added. Further, when the management server 6 in step S501 receives the device identification number from the TV 5 through the network I / F 67 and enters S502, the control signal of the user determination is received from the TV 5 during the control of the flow to be added. The flow changes to S502. The management server 6 determines a control target device based on the transmitted remote control code device with the power ON, and loads data of the control target device from the management device group data unit 60 in step S502.

  Next, a control flow after the device control screen is displayed to the user is shown. First, the control screen will be described using the control screen of the air conditioner of company A in FIG. 8 as an example. 8 includes a control list group 901, a control list 902 of the control list group, a selection frame 906, a remote control screen 907, a current device operation status 908, and a device operation status / history 909. .

  Each control list included in the control list group 901 represents after the state transition of the device. The user selects and determines the control list of the control list button group 901, thereby causing the device to transition to the state indicated by the control list. The control list 902 is one pattern in the control list group 901. A selection frame 906 indicates where on the screen the user is selecting. The user sends an operation signal for moving the selection frame 906 from the TV remote controller 4 to the TV 5 using the input unit 41 of the TV remote controller 4.

  The remote control screen 907 shows the remote control of the current control device on the screen, and is displayed based on the image data storage unit 63 in the management server 6. In addition to the selection of the control list, the user can control the device by the control indicated by the button on the remote control screen 907 by moving the selection frame 906 onto the button on the remote control screen 907 and pressing the determination button to determine the selection. Since the remote control screen 907 is image data related to a device specific to the device, when the control device is selected, the remote control screen 907 is loaded from the management device group data unit 60 in the management server 6 to the image data storage unit 63.

  The current device operation status 908 displays the device operation status. Data to be displayed in the current operation status 908 of the device is recorded in the status storage unit 62 in the management server 6. The operation status / history 909 of the device is displayed based on the data in the state storage unit 62 in the management server 6 such as the model number, the years of use up to now, the usage time of today, the total power consumption, etc., which are basic information of the device. When it is selected as a control device, it is loaded from the management device group data unit 60 in the management server 6 to the state storage unit 62. In addition, since the data in the state storage unit 62 is changed due to control or the passage of time, the operation status / history 909 of the device is also changed.

  Next, based on the control list selected by the user using the TV remote controller 4 from the device control screen shown in FIG. 8, the management server 6 sends a remote control code necessary for control to the TV remote controller 4 via the TV 5. The control target device is controlled such that the remote controller 4 sends the remote control code by infrared rays to the air conditioner 2 to control the air conditioner 2, and the device control screen reflects the change of the device state by the control as shown in FIG. 9. Control until it is displayed on the display unit 51 of the TV 5 will be described with reference to FIGS.

  The processing flow in FIG. 3 starts when the TV remote controller 4 receives an operation signal from the input unit 41. When an operation signal is received from the input unit 41 (step S301), the process enters step S302, the operation signal is transmitted to the TV 5 by the wireless I / F 43, and the process ends. The processing flow in FIG. 4 starts when the TV 5 receives the operation signal from the TV remote controller 4 through the wireless I / F 53.

  When the operation signal of the TV remote controller 4 is received by the wireless I / F 53 and it is a signal for changing the operation position in the screen (step S401), the process goes to step S403, and the control unit 51 of the TV 5 Display screen data is newly created based on the signal, displayed on the display unit 52, and the process ends. In FIG. 8, the operation of moving the selection frame 906 is equivalent.

  When the operation signal of the TV remote controller 4 is received by the wireless I / F 53 and is the operation determination signal (step S401), the control unit 51 of the TV 5 relates to the operation determined by the operation determination signal. A control signal is transmitted to the management server 6 via the network I / F 50, and the process is terminated.

  In FIG. 8, since the selection frame 906 is on the control list 902, the operation determination signal is the control signal indicating that the control list 902 has been selected. The processing flow in FIG. 5 starts when the management server 6 receives the control signal from the TV 5 at the network I / F 67.

  When the control signal is received by the network I / F 67 and the control signal is a control list selection signal, processing of the control list is started. A case where the control list selection signal indicates selection of “eco-cooling” in the control list 902 of FIG. 8 will be described as an example. In the control process of the control list, first, the process enters step S504.

  In step S504, the control unit 66 transmits a control list to the remote control code generation unit 64 based on the control list selection signal. Receiving the control list, the remote control code generation unit 64 reads the state of the device from the state storage unit 62.

  In the case of FIG. 8, based on the control list selection signal, the control unit 66 transmits “Eco-cooling” “power ON / cooling / 28 ° C./direction up / down / air volume auto” to the remote control generation unit 74 as a control list. Receiving the control list, the remote control code generation unit 65 reads out the device status “power ON / cooling / 26 ° C./direction fixed / air flow strength” from the state storage unit 62.

  Next, the process enters step S505. The remote control code generator 64 generates an actual control list from the difference from the control content of the control list. At this time, the remote control code list generation unit 64 derives the difference between the control of the previous control list and the state of the device for each control content category. The classification is a classification based on the control name of the control by the remote control code generator 64, and differs depending on the type of device.

  FIG. 11 shows a part of the remote control cord set of the A company air conditioner. The classification of the air conditioner control by the remote control code generator 64 is “power supply, mode, temperature, direction, air volume, timer, timer time, and others”. The control by the respective remote control codes in FIG. 11 for the control category is as follows: power supply category for operation / stop, mode category for cooling / drying / air blowing, temperature + 1, temperature-1 for temperature category, air volume + 1, air volume-1, The automatic air volume is classified as the air volume classification, the direction up and down is the direction classification, the timer is the timer classification, and the air conditioner cleaning is classified as the other classification. In the other category, controls that are not classified into any category are classified.

  In the case of FIG. 8, the remote control code generation unit 64 has the control list “power ON / cooling / 28 ° C./direction up / down / air volume automatic” and the device status “power ON / cooling / 26 ° C./direction fixed / air volume strong”. The difference is derived for each category. In the power supply category, there is no difference because both the control list and the state of the device are powered on. In the mode section, since the control list and the state of the device are both cooling, there is no difference. In the previous temperature setting category, there is a difference of + 2 ° C. because the control list is 28 ° C. and the state of the device is 26 ° C. In the direction section, there is a difference because the state of the device is fixed (direction up / down OFF) with respect to the control list in the direction up / down. In the air volume classification, there is a difference because the state of the device is strong air volume in the control list with respect to the automatic air volume.

  As a result, in order to shift to the state of the control list, the remote control code generation unit 64 needs + 2 ° C. in the temperature section, up and down in the direction section, and automatic air volume in the air volume section. Then, “+ 1 ° C., + 1 ° C., direction up / down / air volume automatic” is generated as an actual control list.

  Next, the remote control code generation unit 64 reads the remote control code for each control in the actual control list from the remote control code storage unit 61. In the case of FIG. 8, remote control codes of “C1, C1, A1, B4” are received from the remote control code storage unit 61 in correspondence with each control of the actual control list “+ 1 ° C., + 1 ° C., direction up / down / air volume automatic”. The remote control code list shown in FIG. 10 is generated by reading. The remote control code storage unit 61 stores the remote control code set shown in FIG.

  Next, step S506 is entered. The control unit 66 sequentially transmits the remote control codes in the remote control code list received from the remote control code generation unit 64 to the TV 5 through the network I / F 67 from the list. Each time the remote control code is transmitted, step S507 is entered, and the state of the state storage unit 62 is changed based on the control of the transmitted remote control code. The control unit 66 determines completion of transmission of all remote control codes in the remote control code list (step S508), and if not completed, enters step S506 again. Upon completion, the process enters step S509.

  In the case of the remote control code list shown in FIG. 10, in step S506, the control unit 66 transmits the first remote control code “C1” to the TV 5 via the network I / F 67. Next, entering step S507, the control unit 66 changes the state of the state storage unit 62 from 26 ° C. to temperature + 1 ° C. and changes it to 27 ° C. In step S508, the controller 66 determines whether transmission of all remote control codes has been completed or not. Since it is not completed, the control of the control unit 66 enters step S506.

  In step S506, the control unit 66 transmits the second remote control code “C1” in the remote control code list to the TV 5, and in step S507, the state of the state storage unit 62 is changed from 27 ° C. to temperature + 1 ° C. to 28 ° C. change. Since it is not completed (step S508), the control of the control unit 66 enters step S506. In step S506, the control unit 66 transmits the third remote control code “A1” in the remote control code list to the TV 5, and in step S507, the state of the state storage unit 62 is changed from the fixed direction to the vertical direction. Since it is not completed (step S508), the control of the control unit 66 enters step S506. In step S506, the control unit 66 transmits the fourth remote control code “B4” in the remote control code list to the TV 5, and in step S507, the state of the state storage unit 62 is changed from strong air volume to automatic air volume. In step S508, since it is determined that all remote control codes have been transmitted, step S509 is entered.

  In step S509, the control unit 66 transmits a screen change instruction to the control screen generation unit 65. The control screen generation unit 65 reads the device state from the state storage unit 62, reads the image data from the image data storage unit 63, generates a display screen, and transmits the display screen to the control unit 66. The control unit 66 transmits the display screen data to the TV 5 via the network I / F, and ends.

  The processing flow in FIG. 6 starts when the TV 5 receives the display screen data or the remote control code from the management server 6 via the network I / F 50. When the display screen data is received by the network I / F 50 (step S601), the process proceeds to step S603, where the control unit 51 changes the display of the display unit 52 with the received display screen data and ends.

  When the remote control code is received by the network I / F 50 (step S601), the process goes to step S602, where the control unit 51 transmits the received remote control code to the TV remote control 4 by the wireless I / F 53 and ends.

  The processing flow in FIG. 7 starts when the TV remote controller 4 receives the remote control code from the TV 5 by the wireless I / F 43. When the signal received by the wireless I / F is the remote control code (step S701), the control unit 42 enters step S702 and sends the received remote control code to the signal conversion unit 44 to convert it into an infrared signal. Next, in step S703, the infrared transmitter / receiver 45 transmits to the air conditioner 2 and the process ends.

  FIG. 9 shows an example of the control screen after selecting the control list 902 of FIG. FIG. 9 is a display screen of the display unit 52 of the TV 5 after selecting and determining “eco-cooling”. The control list 1002, the current device operation status 1008, and the device operation status / history 1009 are diagrams after the transition of the control list 902, the current device operation status 908, and the device operation status / history 909 of FIG.

  The operation status 1008 of the current device indicates that the device is operating with “cooling”, 28 ° C., direction up / down, and air volume automatic that are “eco-cooling” in the control list 1002. The device operating status / history 1009 indicates that the total usage time, today's usage time, and today's power consumption have increased with respect to the device operating status / history 909 over time.

  So far, the air conditioner 2 has been described for a specific company A, but the present invention is not limited to the company A. The management server 6 obtains the remote control code set, image data, and basic information related to the air conditioner of the B company in the same manner as the remote control code set, image data, and basic information of the device related to the A company. It can be obtained from the company home appliance information server 8.

  Further, the management server 6 can receive the device identification NO from the air conditioner 2 of company B via the TV remote controller 4 and the TV 5. The management server 6 has the remote control code set and device identification number of Company B. Similarly, the control screen generation of company B suitable for the air conditioner 2 of company B, the generation of the remote control code based on the control list, and the control of the remote control code transmission to the air conditioner 2 via the TV 5 and the TV remote control 4 are similarly performed. Can be implemented.

  Next, FIG. 12 shows a control screen for the air conditioner of Company B, and the operation of this system when the air conditioner of Company B is used will be described. The control list group 1301 and the control list 1302 are the same as the control list group 901 and the control list 902 on the control screen for the air conditioner A in FIG. The remote control screen 1307 is image data relating to a device loaded from the management device group data unit 60 of the management server 6 to the image data storage unit 63 when the air conditioner of company B is selected as the control target device.

  The current device operation status 1308 and device operation status / history 1309 are loaded from the management device group data unit 60 of the management server 6 to the state storage unit 62 when the air conditioner of Company B is selected as the control target device. Based on state data. The control list control processing (steps S504 and S505 in FIG. 5) of the management server 6 when the control list 1302 is selected on the control screen of the B company will be described. All other operations are common.

  The remote control code generation unit 64 of the management server 6 receives the control list “power ON / cooling / 28 ° C./direction up / down / air volume automatic” received from the control unit 66, and the device status “power ON / For air conditioning / 26 ° C./direction fixed / air volume 3 ”, a difference is calculated based on the control category“ power source / mode / temperature / direction / air volume / timer / timer time / others ”of the air conditioner. As a result, the remote control code generator 64 derives the difference between the temperature setting category, the direction category, and the air volume category, and generates the actual control list “+ 1 ° C., + 1 ° C., direction up / down / air volume auto”.

  The remote control code generation unit 64 reads the remote control code “C1, C1, A1, B4” corresponding to each control of the actual control list from the remote control code storage unit 61, and the remote control code list shown in FIG. 13 is generated. . A remote control code list shown in FIG. 14 is loaded in the remote control code storage unit 61 from the management device group data unit 60 of the management server 6 when the air conditioner of Company B is selected as the control target device.

  In addition, when adding a new control to a specific air conditioner 2, the manufacturer's home appliance information server sends a new control list to the management server 6 together with the remote control code set and image data, or the user edits the control list. However, this can be realized by adding a combination of controls to be performed.

  As described above, in the user I / F of the present invention, the management server 6 controls the infrared control device via the TV 5 and the TV remote controller 4, and the state change of the infrared control device due to the control is recorded in the state storage unit 62. , Integrated management of the status of household devices with infrared control that are not existing network home appliances.

  For example, the user can check the display screen data based on the record in the state storage unit 62 of the management server 6 on the display unit 52 of the TV 5, thereby making it possible to grasp the device state such as power consumption and usage status. Furthermore, if the manufacturer provides not only a specific manufacturer but also a home appliance information server that provides remote control code sets, image data, and basic device information, home devices manufactured by the manufacturer can be integrated and managed by the management server 6. .

  In addition, since the user I / F of the present invention can define a combination of a plurality of controls as the control list, new control of home appliances that can be performed by a combination of remote control codes by adding the control list to the management server 6 Additional methods are possible. For this reason, device manufacturers can increase the number of user-selectable controls beyond the remote control buttons by providing a combination of controls for their products.

  Further, the management server 6 creates the minimum required remote control code list from the control list and the state of the device as in steps S504 and S505 in FIG. 5 during the control list control, so the number of controls included in the control list. Even if there are many, remote control codes transmitted by infrared rays will not increase proportionally. For this reason, it is possible to increase the number of combinations of control in the control list without increasing the load when the user transmits the remote control code.

  The home appliance operation system according to the present invention presents control in a combination of remote control codes, and based on the current state of the device, transmits only the minimum necessary remote control code to the device from the desired combination of the devices, and proportionally transmits the number of remote control codes transmitted Do not increase.

  For this reason, in the present invention, it is possible to increase the control that can be selected by the user, and it is possible to record the state of the device based on the transmitted remote control code and create information such as power consumption, number of uses, and frequency. The device status can be ascertained, and the remote control code, device status, and image data for controlling multiple devices are recorded on the server. By selecting the device desired by the user, various controls can be performed. Therefore, it is possible to realize home appliance operation that does not limit the types of manufacturers and home appliances, which is useful as a home appliance operation system that remotely controls a plurality of home appliances with a single remote controller.

1 Audio Player 2 Air Conditioner 3 Video Recorder 4 TV Remote Control 5 TV
6 Management server 7 Company A home appliance information server 8 Company B home appliance information server 21, 45 Infrared transmission / reception unit 22 Device identification number storage unit 41 Input unit 42, 51, 66 Control unit 43, 53 Wireless I / F
44 Signal converter 50,67 Network I / F
52 Display Unit 60 Management Device Group Data Unit 61 Remote Control Code Storage Unit 62 Status Storage Unit 63 Image Data Storage Unit 64 Remote Control Code List Generation Unit 65 Control Screen Generation Unit 70 HDD
71 Memory 72 CPU
901,1301 CPU control list group 902,1002, 1302 Control list of control list group 906 Selection frame 907,1307 Remote control screen 908,1008 Current device operation status 909,1009,1309 Device operation status / history

Claims (4)

A home appliance operation system comprising a management server, a television receiver that can communicate with the management server through a network interface, and a remote controller that can communicate with the television receiver through a wireless interface, Is a state storage unit that records the current control state of the device currently controlled by the management server, and a remote control code that records the operation of the device currently controlled by the management server and remote control code data From the state recorded in the state storage unit based on the user-desired control represented by the combination of the operation of the device recorded in the storage unit and the remote control code storage unit and the remote control code included in the remote control code data The resources necessary to realize the control state desired by the user A remote control code generation unit that reads out the concord from the remote control code storage unit; and a control unit that transmits the generated remote control code to the television receiver via a network interface, the television receiver via the network interface from the management server A control unit that transmits the received remote control code to the remote controller via the wireless interface, the remote controller sending a remote control code received from the television receiver via the wireless interface to a signal conversion unit, and an infrared signal of the remote control code; A home appliance operation system comprising a signal conversion unit for performing conversion into an infrared ray and an infrared transmission / reception unit. The state storage unit includes a device state, a current control state, and a control time record, and the management server stores an image data storage unit that stores image data relating to the device, the state storage unit, and the image data storage unit. A control screen generating unit that generates display screen data reflecting the control state of the current device, and a control unit that transmits the display screen data through a network interface, wherein the television receiver displays the display received through the network interface. The home appliance operation system according to claim 1, further comprising a display unit that displays screen data. The management server includes a management device group data section that records the operation of the device, remote control code data, the device status, and image data related to the device of a plurality of infrared operation devices managed in the home. The home appliance operation according to claim 1, further comprising a control unit that loads data into the remote control code storage unit, the state storage unit, and the image data storage unit based on a user's device selection. system. The appliance operation system according to claim 2, wherein the device state includes a state / time at the time of final operation when the management server controls the device, a total use time, power consumption, and a use period.

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