KR102389710B1 - Legacy home appliance control method using context awareness and system supporting it - Google Patents

Abstract

The present invention relates to a method for controlling a legacy home appliance through situational awareness and a system supporting the same, and more particularly, to a method for controlling a legacy home appliance using environmental information collected from a sensor.
To this end, the legacy home appliance control system of the present invention includes: a measuring device that is located in the house and collects environmental data and power consumption; an IR blaster located in the premises, including a first measurement module for collecting environmental data, and outputting an IR signal for remotely controlling a legacy home appliance located in the premises; and a second measurement module located in the house and collecting environmental data, using the environmental data collected by the first measurement module constituting the measurement device and the IR blaster and the environmental data collected by the second measurement module and a hub that analyzes a home environment and transmits a control signal for remotely controlling a legacy home appliance that requires remote control according to the analyzed home environment to the IR blaster.

Description

Legacy home appliance control method using context awareness and system supporting it

The present invention relates to a method for controlling a legacy home appliance through situational awareness and a system supporting the same, and more particularly, to a method for controlling a legacy home appliance using environmental information collected from a sensor.

The existing home appliance control method connects to a gateway of the home network through an application for controlling the home appliances connected to the home network, receives device information on the home appliances connected to the home network, and provides a user with an operation on the home appliances It provides status information and controls the home appliances according to a user's motion input.

However, in the existing home appliance control method, it is difficult to simultaneously control a plurality of home appliances at once, and it is difficult to provide a basic operation suitable for a new home appliance to a user.

In addition, as the requirements for IoT smart home increase recently, technologies for controlling various home appliances have been developed, but these products apply two-way communication capable of receiving and transmitting data. However, many legacy (IR) products are still being used or being produced due to existing products or price factors. Legacy products have a problem in that it is difficult to check the operation status of the product because it performs unidirectional communication due to the characteristics of the signal or the product itself, and therefore there is a problem in that it cannot be accurately controlled according to the operation status of the product.

Korean Patent Laid-Open Patent No. 2015-0005746 (Title of Invention: Home Appliance Remote Control Method and Apparatus) Korean Patent Laid-Open Patent No. 2005-0123201 (Title of Invention: Home Appliance Remote Control System)

The problem to be solved by the present invention is to propose a method for checking the operating state of a legacy home appliance that performs one-way communication.

Another problem to be solved by the present invention is to propose a method for controlling the operation of a legacy home appliance that performs one-way communication.

Another problem to be solved by the present invention is to propose a method for checking and controlling the operating state of a legacy home appliance capable of IR communication.

To this end, the legacy home appliance control system of the present invention includes a measuring device that is located in the house and collects environmental data and power consumption; an IR blaster located in the premises, including a first measurement module for collecting environmental data, and outputting an IR signal for remotely controlling a legacy home appliance located in the premises; and a second measurement module located in the house and collecting environmental data, using the environmental data collected by the first measurement module constituting the measurement device and the IR blaster and the environmental data collected by the second measurement module and a hub that analyzes the home environment and transmits, to the IR blaster, a control signal for remotely controlling a legacy home appliance that requires remote control according to the analyzed home environment.

To this end, the legacy home appliance control system of the present invention includes a measuring device that is located in the house and collects environmental information and power consumption; and a measurement module located in the premises and collecting environmental information, analyzing the indoor environment using the environmental data collected by the measurement device and the measurement module, and requiring remote control according to the analyzed in-house environment. and a hub for outputting a control signal for remote control of the device through IR communication.

The legacy home appliance control system according to the present invention analyzes the operating state of the legacy home appliance located in the house by using the environment information collected from the measuring device or the measuring module for measuring the indoor environment, and for controlling the analyzed operating state of the legacy home appliance By creating and outputting a remote control device, it is possible to control the operating state of the legacy home appliance. That is, in order to control the legacy home appliance that cannot provide its own state information, it is possible to efficiently control the legacy home appliance by using a sensor that collects in-house environment information.

1 illustrates a legacy home appliance control system through situational awareness according to an embodiment of the present invention.
Figure 2 shows a legacy home appliance control system through situation recognition according to another embodiment of the present invention.
3 illustrates an example of checking the status of a legacy home appliance by using measurement data in the hub according to an embodiment of the present invention.
Figure 4 shows the operation of the legacy home appliance control system through situation recognition according to an embodiment of the present invention.

The foregoing and further aspects of the present invention will become more apparent through preferred embodiments described with reference to the accompanying drawings. Hereinafter, it will be described in detail so that those skilled in the art can easily understand and reproduce through these embodiments of the present invention.

1 illustrates a legacy home appliance control system through situational awareness according to an embodiment of the present invention. Hereinafter, a legacy home appliance control system through situational awareness according to an embodiment of the present invention will be described in detail with reference to FIG. 1 .

Referring to FIG. 1 , the legacy home appliance control system 100 through context awareness includes a hub 110 , an IR blaster 120 , and a measurement device 130 . Of course, other configurations in addition to the above-described configuration may be included in the legacy home appliance control system through whether the situation proposed by the present invention. As an example, the legacy home appliance may be included in the legacy home appliance control system based on the situation proposed by the present invention.

The hub 110 includes a communication unit, a control unit, a storage unit, and the like, and the communication unit performs wired communication or wireless communication. In particular, the hub 110 includes a wireless communication module for interworking with the IoT device. That is, the hub 110 not only controls the legacy home appliance, but also communicates with the IoT device, and includes a communication module capable of communicating with the IoT device for this purpose.

The hub 110 uses the measurement data provided from the IR blaster 120 or the measuring device 130 to determine the operating state of the legacy home appliance, and generates a control signal for controlling the legacy home appliance to the IR blaster 120. to provide. Of course, the hub 110 uses the measurement data provided from the IR blaster 120 or the measurement device 130 as well as the measurement data collected from the built-in measurement module to determine the operating state of the legacy home appliance. Referring to FIG. 1 , the hub 110 is illustrated as including a volume determination engine and a temperature/humidity sensor, but is not limited thereto. Any measurement module capable of measuring the indoor environment may be included in the hub according to the user's selection, and the hub uses the corresponding measurement module to determine the status of the legacy home appliance. A detailed operation of the hub will be described later.

The IR blaster 120 includes a wired module or a wireless module, and in particular includes a measurement module. According to FIG. 1 , the IR blaster 120 includes a microphone and a measurement module including a temperature and humidity sensor, but is not limited thereto. Similarly to the above-described hub, the IR blaster may be included in the IR blaster according to a user's selection if it is a measurement module capable of measuring the indoor environment.

The IR blaster 120 provides measurement data measured by the measurement module to the hub. For communication between the hub 110 and the IR blaster 120 , any one of wired communication and wireless communication is applied. The IR blaster 120 receives a control signal for controlling the legacy appliance from the hub 110 . The IR blaster 120 transmits the received control signal to the outside through IR communication. Of course, according to the control signal transmitted by the IR blaster 120, the legacy home appliance performs the operation included in the control signal.

As such, the IR blaster 120 proposed by the present invention includes an IR communication module to control the legacy home appliance, and transmits a remote control signal for controlling the legacy home appliance using this.

In addition, a plurality of measuring devices 130 are included in the house. Referring to FIG. 1 , various types of measuring devices 130 such as an energy meter, a photosensor, an illuminance sensor, or a temperature/humidity sensor are disposed in the house. The measuring device 130 disposed in the house provides the measured data to the hub. The measuring device 130 communicates with the hub by using any one of wireless communication or wired communication.

As described above, the present invention collects the indoor environment by using a measurement module or a measurement device installed in the premises of the state of the legacy home appliance that cannot provide its own state information, and uses the collected indoor environment information, the measurement data, of the legacy home appliance. By understanding the current state, it is possible to control the state of the legacy home appliance.

1 , the hub and the IR blaster include a volume determination engine and a temperature and humidity sensor. When the IR blaster is connected to and interlocked with the hub, the hub's temperature and humidity sensor may stop running. That is, the indoor environment can be measured using the temperature and humidity sensor constituting the IR blaster.

In addition, when the power of the energy meter is cut off, the hub recognizes a power outage or an emergency situation and performs a necessary operation. In addition, the hub includes an input means including a wall pad, and a user can directly input a control signal using the input means.

If the installation location of the hub and the IR blaster is close to each other, the hub's temperature/humidity sensor stops driving, and the indoor environment is measured using the temperature/humidity sensor of the IR blaster located close to the hub.

If the installation location of the hub and the IR blaster is not located close to each other (more than the set distance), both the temperature and humidity sensor of the hub and the temperature and humidity sensor of the IR blaster are driven to measure the indoor environment of the hub and the IR blaster, respectively. If the IR blaster is installed in multiple locations, the temperature and humidity sensor is driven individually for each IR blaster to measure the indoor environment.

In addition, in the location where the hub and IR blaster are installed (living room, each room, kitchen, etc.), the air conditioner, fan, etc. may be in the operating state (On) or in the operating state (Off) to measure and manage the indoor environment. That is, it determines whether the temperature/humidity sensor is driven by determining the environment at the point where the temperature/humidity sensor is installed. For this, the hub stores information on the location where the temperature/humidity sensor is installed.

In connection with the present invention, the volume determination engine determines whether the legacy home appliance is actually driven when the driving of the legacy home appliance is instructed. That is, instead of determining the driving continuation state of the legacy home appliance, it is determined whether the legacy home appliance is on/off. Therefore, the signal generated at the time of driving instruction is an important factor. In general, in the case of home appliances such as air conditioners or air purifiers, a unique signal is transmitted when the power is turned on. The present invention determines whether the home appliance is driven by using whether such a unique signal sound is transmitted.

Of course, if necessary, it is possible to determine whether the home appliance is driven by using the noise generated when the motor is driven in addition to the unique signal sound. The sound-based recognition proposed by the present invention stores a sound pattern according to the driving of the home appliance, analyzes the received sound, and compares it with the stored sound pattern to determine whether the home appliance is driven.

The energy meter synchronizes with the volume determination engine, and when the IR blaster instructs to drive the legacy home appliance, it instantly senses the change in energy, and the hub determines whether the home appliance is driven in parallel with the volume determination engine as described above. do.

Of course, if one sound is not heard because the other sound is buried, the energy meter alone determines whether the home appliance is running, but in general, the situation in which the sound is not completely audible rarely occurs, can extract and analyze the desired acoustic pattern.

Figure 2 shows a legacy home appliance control system through situation recognition according to another embodiment of the present invention. Hereinafter, a legacy home appliance control system through situation recognition according to another embodiment of the present invention will be described in detail with reference to FIG. 2 .

Referring to FIG. 2 , the legacy home appliance control system 200 through context awareness includes a hub 210 and a measuring device 230 . Of course, other configurations in addition to the above-described configuration may be included in the legacy home appliance control system through whether the situation proposed by the present invention. As an example, the legacy home appliance may be included in the legacy home appliance control system based on the situation proposed by the present invention.

The hub 210 includes a communication unit, a control unit, a storage unit, and the like, and the communication unit performs wired communication or wireless communication. In particular, the hub 210 includes a wireless communication module for interworking with the IoT device. That is, the hub 210 not only controls the legacy home appliance, but also communicates with the IoT device, and includes a communication module capable of communicating with the IoT device for this purpose.

The hub 210 uses the measurement data provided from the measurement device 230 to determine the operating state of the legacy home appliance, and generates and outputs a control signal for controlling the legacy home appliance. Of course, the hub 210 uses the measurement data provided from the measurement device 230 as well as the measurement data collected from the built-in measurement module to determine the operating state of the legacy home appliance. Referring to FIG. 2 , the hub 210 is illustrated as including a volume determination engine and a temperature/humidity sensor, but is not limited thereto. Any measurement module capable of measuring the indoor environment may be included in the hub according to a user's selection, and the hub 210 uses the corresponding measurement module to determine the state of the legacy home appliance. The hub 210 transmits a control signal for controlling the legacy home appliance to the outside through IR communication. Of course, the legacy home appliance performs the operation included in the control signal according to the control signal transmitted by the hub 210 . A detailed operation of the hub will be described later.

As described above, the hub 210 proposed by the present invention includes an IR communication module to control the legacy home appliance, and transmits a remote control signal for controlling the legacy home appliance using this.

In addition, a plurality of measuring devices 230 are included in the house. Referring to FIG. 2 , various types of measuring devices such as an energy meter, a photosensor, an illuminance sensor, or a temperature/humidity sensor are disposed in the house. The measuring device 230 disposed in the house provides the measured data to the hub. The measuring device 230 communicates with the hub using any one of wireless communication or wired communication.

As described above, the present invention collects the indoor environment by using a measurement module or a measurement device installed in the premises of the state of the legacy home appliance that cannot provide its own state information, and uses the collected indoor environment information, the measurement data, of the legacy home appliance. By understanding the current state, it is possible to control the state of the legacy home appliance.

Hereinafter, an operation performed by the measuring device or the measuring module will be described. The energy meter measures the current power consumption, and the photosensor and the illuminance sensor measure the brightness of the house. The temperature and humidity sensor measures the temperature and humidity of the house, and the volume determination engine measures the noise level of the house. In addition, a measuring device for measuring various environmental information is installed in the house, and the measuring device provides the measured data to the hub.

3 illustrates an example of checking the status of a legacy home appliance by using measurement data in the hub according to an embodiment of the present invention. Hereinafter, an example of checking the status of a legacy home appliance using measurement data in the hub according to an embodiment of the present invention will be described in detail with reference to FIG. 3 .

As described above, the hub checks the status of the legacy home appliance by using the measurement data provided from the measurement device or the measurement module. In particular, the present invention utilizes a measuring device or a measuring module other than the energy meter. When checking the status of legacy home appliances only with an energy meter, when data is provided and analyzed in real time, the load is heavy due to the amount of power data, and accurate judgment cannot be made when multiple legacy home appliances are driven at the same time. Therefore, the hub of the present invention determines the operating state of the legacy home appliance by using measurement data measured by a device other than the energy meter.

For example, in the case of a TV, it is determined whether the TV is on/off and the volume level using measurement data provided from a volume determination engine, an energy meter, and an illuminance sensor. If it is judged that power is consumed by the energy meter, the brightness of the house is higher than the brightness set by the illuminance sensor, and the noise level is higher than the set level by the volume determination engine, the hub determines that the TV is currently on and the TV is off. Send an IR signal directly to the TV if required, or request an IR blaster to send an IR signal requesting the TV to be powered off.

In the case of an air conditioner, it is determined whether the air conditioner is on/off using the measurement data provided from the volume determination engine, the energy meter, and the temperature and humidity sensor. If it is judged that power is consumed by the energy meter, the temperature in the house is below the set temperature by the temperature and humidity sensor, and the noise level is higher than the set level by the volume determination engine, the hub determines that the air conditioner is currently on, and the air conditioner is turned off. If required, send an IR signal directly to the air conditioner, or request an IR blaster to send an IR signal requesting to turn off the air conditioner. Of course, the level of noise determined to be turned on and the amount of noise determined to be turned on can be set differently.

In the case of a set-top box (STB), it is determined whether the set-top box is turned on or off using the measurement data provided from the volume determination engine and the energy meter. It is judged that power is consumed by the energy meter, and if the noise level is greater than the set level by the volume determination engine, the hub determines that the set-top box is currently turned on. or send an IR signal requesting to power off the set-top box with the IR blaster.

In the case of a fan, it is determined whether the fan is on/off using the measurement data provided from the volume determination engine, the energy meter, and the temperature and humidity sensor. If it is determined that power is consumed by the energy meter, the temperature in the house is below the set temperature by the temperature and humidity sensor, and the noise is higher than the set level by the volume determination engine, the hub determines that the fan is currently on, and the fan will be turned off. If required, send an IR signal directly to the fan, or request an IR blaster to send an IR signal requesting that the fan be turned off.

In the case of lighting, it is determined whether the lighting is on/off using the measurement data provided from the energy meter and the illuminance sensor. It is judged that power is consumed by the energy meter, and if the brightness of the house is higher than the set brightness by the illuminance sensor, the hub determines that the current light is on. Or, it asks the IR blaster to send an IR signal requesting that the light be turned off.

A sound source can be analyzed using a sound source analysis algorithm that simply measures the size of the noise in the volume determination engine. By the procedure of analyzing the sound source as described above, the hub can determine the cause of the noise more accurately than simply measuring the size of the noise, and through this, the type of legacy home appliance that is the cause of the noise can be determined.

Figure 4 shows the operation of the legacy home appliance control system through situation recognition according to an embodiment of the present invention. Hereinafter, the operation of the legacy home appliance control system through situational awareness according to an embodiment of the present invention will be described in detail with reference to FIG. 4 .

Referring to FIG. 4 , the legacy home appliance control system 400 through context awareness includes a hub 410 , an IR blaster 420 , a measuring device 430 , and a legacy home appliance 440 . Of course, other configurations in addition to the above-described configuration may be included in the legacy home appliance control system 400 through whether the situation proposed by the present invention.

The measuring device 430 measures and collects environmental data (measured data). As described above, the measuring device 430 includes an energy meter, an illuminance sensor, a photosensor or a temperature/humidity sensor. The measurement device 430 provides the collected measurement data to the hub 410 .

The IR blaster 420 measures and collects environmental data (measured data) using a measurement module. As described above, the measurement module includes a volume determination engine, a temperature and humidity sensor, and the like. The IR blaster 420 provides the collected measurement data to the hub 410 .

The hub 410 measures environmental data using a measurement module. As described above, the measurement module includes a volume determination engine, a temperature and humidity sensor, and the like. The hub 410 checks the status of legacy appliances located in the house based on the environmental data measured by the built-in measurement module, the environmental data provided from the measuring device 430 , and the environmental data provided from the IR blaster 420 .

The hub 410 extracts information on legacy home appliances that require control from among the legacy home appliances located in the house. As an example, information on legacy home appliances that require stopping the operation of the currently driven legacy home appliances is extracted.

The hub 410 transmits a control signal for controlling the legacy home appliance to the IR blaster 420 corresponding to the legacy home appliance that requires control.

The IR blaster 420 transmits the control signal provided from the hub 410 in the direction of the legacy appliance using IR communication.

The legacy home appliance 440 performs an operation corresponding to the IR signal transmitted by the IR blaster 420 . As such, the present invention uses the hub 410 or the IR blaster 420 to determine the state of the legacy home appliance 440, and according to the identified state of the legacy home appliance 440, a control signal for controlling the legacy home appliance 440 is IR It transmits to the legacy appliance 440 using communication.

In addition, according to the present invention, a plurality of IR blasters 420 may be installed in the house, and the hub 410 stores information on legacy appliances 440 controlled by each IR blaster 420 . The hub 410 provides a control signal to the IR blaster 420 that controls the legacy home appliance that requires control by using the stored information. In other words, in the case where a plurality of legacy home appliances 440 are disposed in the house and it is desired to control the legacy home appliances 440 using IR communication with strong straightness, multiple of IR blaster 420 is required. In addition, when a plurality of IR blasters 420 are disposed in the house, the hub 410 stores information about the legacy home appliances 440 performing IR communication with each IR blaster 420, and uses the stored information to store information. A control signal for controlling a legacy appliance is provided to any one of the plurality of IR blasters 410 by the IR blaster 420 .

In addition, the present invention may drive a measuring device or a measuring module in various forms. For example, when the environmental data measured by at least two measurement modules is within the error range, any one measurement module measures the environmental data, and when the measured environmental data is out of the error range, the measurement is performed by at least two measurement modules. Collect and use environmental data. As described above, the present invention may collect environmental data in various forms.

In relation to the present invention, when using an IR blaster and a hub, the IR blaster outputs an IR signal. In particular, it is preferable that the IR blaster outputs an IR signal in a 360° omnidirectional direction. Make the IR signal output in the ° direction.

In addition, if there is no change in the indoor environment after the IR blaster or hub outputs the IR signal, the IR blaster or the hub re-outputs the IR signal and, if necessary, notifies the user.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and it will be understood by those skilled in the art that various modifications and equivalent other embodiments are possible therefrom. .

100: legacy appliance control system 110: hub
120: IR blaster 130: measuring device
200: legacy appliance control system 210: hub
230: measuring device 400: legacy home appliance control system
410: hub 420: IR blaster
430: measuring device 440: legacy appliances

Claims (8)

a measuring device that is located in the house and collects environmental data and power consumption;
an IR blaster located in the premises, including a first measurement module for collecting environmental data, and outputting an IR signal for remotely controlling a legacy home appliance located in the premises; and
It is located in the premises and includes a second measurement module for collecting environmental data, and uses the environmental data collected by the first measurement module constituting the measurement device and the IR blaster and the environmental data collected by the second measurement module. A hub that analyzes an environment and transmits a control signal for remote control of a legacy home appliance that requires remote control according to the analyzed home environment to the IR blaster,
The hub determines whether the legacy home appliance is driven by using the environmental data collected from at least two or more measurement modules to determine whether the legacy home appliance is driven,
When the IR blaster and the hub are located in the house, the IR blaster outputs an IR signal for controlling the legacy home appliance at an angle of 360°,
When the environmental data measured by the two measurement modules is within the error range, the indoor environment is analyzed using the environmental data measured by one of the measurement modules, and when the environmental data measured by the two measurement modules is out of the error range analyzes the indoor environment using the environmental data measured by the two measurement modules,
The hub stores information about legacy appliances that perform IR communication with the IR blaster installed in the house, and transmits a control signal to the IR blaster that communicates with the legacy appliance that requires control by using the stored information,
The hub stops the operation of the temperature and humidity sensor included in the built-in second measurement module when the IR blaster is connected and interlocked,
The hub stops driving the temperature and humidity sensor included in the hub when the installation position of the IR blaster is less than a set distance from the hub,
When the IR blaster instructs to drive the legacy home appliance, it is determined whether the legacy home appliance is driven by paralleling the signal sound of the legacy home appliance recognized by the synchronized volume determination engine and the amount of energy change detected by the energy meter,
The hub or IR blaster contains a volume determination engine,
The legacy home appliance control system, characterized in that it is determined by determining whether the legacy home appliance is driven by using a unique signal sound generated when the legacy home appliance is instructed to drive.
The method of claim 1, wherein the IR blaster and the hub perform two-way communication,
The legacy appliance control system, characterized in that the IR blaster and the legacy appliance perform IR communication.
The method of claim 2, wherein the measuring device comprises an energy meter for collecting consumed power,
The hub analyzes the indoor environment using the power consumption received from the energy meter and at least one environment data.
4. The method of claim 3, wherein the hub transmits the control signal to the IR blaster if the environmental data collected after transmitting the control signal to the IR blaster is within a set error range with the environmental data collected before providing the control signal. Legacy home appliance control system, characterized in that the retransmission to.
delete delete The legacy home appliance control system according to claim 1, wherein the hub includes an input means for receiving a control command for generating a control signal.
delete

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