KR102001253B1 - Ibm cloud based smart home touch switch system and operating method thereof - Google Patents

Abstract

Disclosed are an IBM cloud-based smart home touch switch system and an operation method thereof. The IBM cloud-based smart home touch switch system comprises: an IoT touch switch which performs on/off switching of a lighting device depending on a user′s touch input or a wireless input command, and senses and transmits the temperature in real time by using a pre-built temperature sensor; a user terminal which transmits the wireless input command for on/off switching of the IoT touch switch; and an IBM cloud which receives the wireless input command from the user terminal and transmits an on/off switching control command of the IoT touch switch according to the received wireless input command to the IoT touch switch. The IBM cloud includes: a Watson IoT platform for receiving the temperature in real time from the IoT touch switch and transmitting the wireless control command for controlling the temperature based on the temperature received in real time to the IoT touch switch; a Cloudant and object storage for storing the temperature received in real time from the Watson IoT platform; Apache spark for extracting necessary profile data by using the temperature stored in the object storage; DB data warehouse for building profile data; a Watson studio for redefining the criteria for abnormality based on the profile data; and a cloud application for generating an alarm generation command and a control command for determining the abnormality and controlling the temperature according to the determination result. According to the present invention, it is possible to automatically control a lighting device from a remote place.

Description

IBM cloud-based smart home touch switch system and its operation method {IBM CLOUD BASED SMART HOME TOUCH SWITCH SYSTEM AND OPERATING METHOD THEREOF}

The present invention relates to a touch switch system and a method of operating the same, and more particularly, to an IBM cloud-based smart home touch switch system and a method of operating the same.

Smart home is composed of IoT (Internet of Things) technology to collect a variety of information in real-time and integrated control.

The user terminal of the user may remotely monitor the smart home device and remotely control the devices of the smart home.

IBM's IBM cloud is also applicable to smart homes.

On the other hand, it is possible to control a variety of indoor devices, such as home or office, this integrated control requires a complex algorithm.

Further complexity and efficiency are required for algorithms that can control and optimize various sensors and devices.

10-1859715 10-2018-0117989

An object of the present invention to provide an IBM cloud-based smart home touch switch system.

Another object of the present invention to provide an operating method of the IBM cloud-based smart home touch switch system.

The IBM cloud-based smart home touch switch system according to the above-described object of the present invention performs on / off switching of a lighting device according to a user's touch input or a wireless input command and uses a pre-built temperature sensor. IoT touch switch for sensing the temperature using the real-time transmission (IoT touch switch); A user terminal transmitting a wireless input command for on / off switching of the IoT touch switch; Receives a wireless input command from the user terminal and transmits an on / off switching control command of the IoT touch switch according to the received wireless input command to the IoT touch switch, and receives the temperature from the IoT touch switch in real time and received in real time Watson IoT platform that transmits a wireless control command to control the temperature based on temperature to the IoT touch switch, Cloudant and object storage in which the temperature received in real time from the Watson IoT platform is stored. Object storage), Apache spark to extract the required profile data using the temperature stored in the object storage, DB data warehouse to build the profile data, DB data warehouse to build and learn the profile data Watson Studio redefines the criteria Watson studio), may be configured to include an IBM cloud (Cloud) consisting of a cloud application (Cloud application) for generating a control command and alarm generation command for determining the abnormality and controlling the temperature according to the determination result.

Method 1 of operating the IBM cloud-based smart home touch switch system according to another object of the present invention described above (1), the user terminal is connected to the IBM cloud (IBM cloud) to perform a subscription; Transmitting, by the user terminal, a wireless input command to a Watson IoT platform of the IBM cloud according to a user input; Receiving, by the Watson IoT platform, a wireless input command and transmitting a wireless input command to the IoT touch switch so that the corresponding IoT touch switch can be controlled; Receiving, by the IoT touch switch, a wireless input command of the Watson IoT platform and controlling an on / off switching of a light; The light switch may be configured to include a step of turning on / off.

Second (Fig. 3) of the operation method of the IBM cloud-based smart home touch switch system according to another object of the present invention, the user terminal is connected to the IBM cloud (IBM cloud) to perform a subscription; Sensing a temperature using an IoT sensor in which an IoT touch switch is pre-built and transmitting the real time to a Watson IoT platform of an IBM cloud; The Watson IoT platform receives the temperature in real time and stores the cloud as a Watson IoT database of Cloudant through a service interworking module of the cloud application, and the Watson IoT database is stored in a long data map database of object storage. Accumulating and storing data; Apache spark's profile data extraction module extracts the required profile data from the big data map database in Object storage, and the profile data building module in the DB data warehouse is profiled. Building data; The Watson IoT platform receives the temperature in real time, and the Watson studio redefines the criterion by analyzing the data according to the user pattern; Checking whether the sensing value determination module of the cloud application is abnormal based on the redefined criterion; Generating an alarm when there is an abnormality in the cloud application, and transmitting an alarm generated by an alarm transmission module to a user terminal in real time; And the user terminal is configured to include receiving and outputting an alarm.

According to the above-described IBM cloud-based smart home touch switch system and its operation method, it is configured to implement the IoT smart home indoors by building a touch switch (network) capable of networking, it is possible to remotely control the lighting equipment It has an effect.

On the other hand, it is configured to detect and control the air quality environment such as indoor temperature, humidity, fine dust, gas leaks, etc., so that the indoor environment can be automatically optimized, and the indoor environment can be pre-controlled to create environment for each user. It is effective, and it is possible to determine whether to be occupied based on the location of the user.

In addition, if there is an abnormality in the result of the determination of the received temperature in real time, an alarm is generated and transmitted to the user terminal in real time, so that the user can cope early in the event of fire.

1 is a block diagram of an IBM cloud-based smart home touch switch system according to an embodiment of the present invention.
2 is a flow chart of a lighting device control operation method of the IBM cloud-based smart home touch switch system according to an embodiment of the present invention.
3 is a flowchart illustrating an alarm output operation method of an IBM cloud-based smart home touch switch system according to an exemplary embodiment of the present invention.

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in order to practice the invention. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements.

Terms such as first, second, A, and B may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. The term and / or includes a combination of a plurality of related items or any item of a plurality of related items.

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may be present in between. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the present invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, operation, component, part, or combination thereof described in the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, components, or a combination thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

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

1 is a block diagram of an IBM cloud-based smart home touch switch system according to an embodiment of the present invention.

Referring to FIG. 1, the IBM cloud-based smart home touch switch system according to an embodiment of the present invention includes an IoT touch switch (Internet of Things touch switch) 100, a user terminal 200, and an IBM cloud (International Business Machines cloud). 300).

The IBM cloud-based smart home touch switch system 100 enables networking with the IoT touch switch 100 and enables the IoT touch switch 100 to detect temperature, humidity, fine dust, gas, etc. Build your environment.

The IBM cloud-based smart home touch switch system 100 may be configured to control the lighting device 10 as well as temperature control, humidity control, fine dust reduction control, gas emission control, and the like based on the cloud application.

And based on the location of each user, navigation (Navigation) information and the user's body / emotional information can be configured to pre-construct each user's indoor environment.

Hereinafter, the detailed structure is demonstrated.

The IoT touch switch 100 may be configured to perform on / off switching of the lighting device 100 according to a touch input of the user or a wireless input command received from the user terminal 200 of the user.

In addition, the IoT touch switch 100 is equipped with an IoT function to sense various indoor environments and provide them to the IBM cloud 300, as well as to provide an air conditioning and heating device 20, a humidifier 30, an air purifier 40, and a window automatic. It is configured to control the switch 50 and the like.

The IoT touch switch 100 includes a touch input module 101, a wireless input command receiving module 102, an on / off switching module 103, a temperature sensor 104, a humidity sensor 105, and a fine dust sensor 106. , The gas detection sensor 107, the IoT control module 108, and the sensing value transmission module 109 may be configured. Hereinafter, the detailed structure is demonstrated.

The touch input module 101 may be configured to receive a touch input from a user indoors. The touch input is an input for on / off switching of the lighting device 10.

The wireless input command receiving module 102 may be configured to receive a wireless input command from the user terminal 200 through the IBM cloud 300. The wireless input command, as well as the on / off control command of the lighting device 10, the air-conditioning device 20, the humidifier 30, the air cleaner 40, the window automatic switch 50, the TV 60, the audio device ( 70) can be a command for control.

The on / off switching module 103 may be configured to switch on / off the lighting device 10 by a touch input of the touch input module 101 or a wireless input command received by the wireless input command receiving module 102. .

The temperature sensor 104 may be configured to sense the temperature of the room. The IoT touch switch 100 may be sensed in each room or each zone where the IoT touch switch 100 is installed.

The humidity sensor 105 may be configured to sense the humidity of the room. The IoT touch switch 100 may be sensed in each room or each zone where the IoT touch switch 100 is installed.

The fine dust sensor 106 may be configured to sense fine dust introduced into the room.

The gas detection sensor 107 may be configured to detect a leak in a kitchen or boiler. The IoT touch switch 100 may be sensed in each room or each zone where the IoT touch switch 100 is installed.

The IoT control module 108 controls the indoor environment based on the temperature, humidity, fine dust, and gas sensed by the temperature sensor 104, the humidity sensor 105, the fine dust sensor 106, and the gas detection sensor 107, respectively. It may be configured to control each of the air-conditioning device 20, the humidifier 30, the air cleaner 40, the automatic window opener 50 provided in each room so as to optimize. If the temperature is too low or high, the air conditioning and heating device 20 may be operated. If the humidity is low, the humidifier 30 may be operated. If there is a lot of fine dust may be configured to close the window by operating the air purifier 40 and driving the automatic window opener (50). If necessary, the air can be ventilated by opening and closing the window by driving the window automatic switch 50 at a predetermined time. If gas is detected, the window may be quickly ventilated by opening the window using the automatic window switch 50.

Sensing value transmission module 109 in real time the temperature, humidity, fine dust, gas sensing values sensed by the temperature sensor 104, humidity sensor 105, fine dust sensor 106, gas detection sensor 107, respectively It may be configured to transmit to the IBM cloud 300.

The user terminal 200 may be a mobile terminal such as a smart phone carried by the user. The user terminal 200 may be configured to communicate with the IoT touch switch 100 remotely indoors and outdoors through an application to monitor the indoor environment in real time and to remotely control various devices.

The user terminal 200 includes a command input module 201, a wireless input command transmitting module 202, an alarm receiving module 203, an alarm output module 204, a navigation collection module 205, and a location / arrival time information transmitting module. 206, the user body / emotional information collection module 207, the SNS analysis module 208, and the user body / emotional information transmission module 209. Hereinafter, the detailed structure is demonstrated.

The command input module 201 may be configured to receive a command for monitoring an indoor environment or a command for remotely controlling various devices from a user.

The wireless input command transmitting module 202 may be configured to transmit the wireless input command corresponding to the command received from the command input module 201 to the IBM cloud 300 in real time.

A user may recognize a danger of an indoor environment, input a command corresponding thereto, and transmit the same, and may monitor the automatic remote response process of the IBM cloud 300 in real time.

The alarm receiving module 203 may be configured to receive an alarm of the cloud application 300a when it is determined that the indoor environment is dangerous by the cloud application 300a of the IBM cloud 300.

The alarm output module 204 may be configured to output an alarm received at the alarm receiving module 203.

The navigation collection module 205 may be configured to collect navigation information from a navigation application provided in the user terminal 200. The navigation information may be information such as a user's current location, destination, estimated time of arrival, and the like.

Here, the navigation may include all vehicle navigation, public transportation navigation, walking navigation, and the like. The navigation application can be configured to run in background mode. The navigation collection module 205 may control the navigation application installed in the user terminal 200 to be executed in the background mode when the user is outdoors. When run in background mode, it can only collect information such as your current location, destination, and estimated time of arrival.

The location / arrival time information transmission module 206 may be configured to transmit, in real time, the navigation information collected by the navigation collection module 205 to the IBM cloud 300.

The user body / emotional information collection module 207 may be configured to collect body / emotional information of the user. The user body / emotional information may basically include bio rhythm information of the user and may include a stress index measured by the user terminal 200. In addition, the blood pressure information input by the user may be included.

The SNS analysis module 208 may be configured to perform text mining on an SNS application installed on the user terminal 200 to analyze and infer the current mood, emotion, and physical state of the user. An example of the user's body / emotional information may be "bad", "fun", "tired", or "angry" in the user's SNS article.

The user body / sensibility information transmission module 209 transmits the body / emotional information of the user collected by the user body / emotional information collection module 207 and the body / emotional information of the user analyzed by the SNS analysis module 208 to the IBM cloud ( 300 may be configured to transmit in real time.

The IBM cloud 300 connects the remote user terminal 200 and the indoor IoT touch switch 100 and analyzes the sensing values sensed by the IoT touch switch 100 to automatically integrate and control various devices. Can be.

The IBM cloud 300 can remove the dangerous indoor environment and optimize the indoor environment through artificial intelligence, create an optimal indoor environment for each user, and send an alarm to the user terminal 200 in a dangerous situation such as a fire. It is composed.

IBM cloud 300 is a cloud application (300a), Watson IoT platform (300b), Cloudant (300c), Object storage (300d), Apache Spark ( Apache spark) 300e, DB data warehouse 300f, and Watson studio 300g.

The cloud application 300a interlocks and controls the service of the IBM cloud 300 and transmits an alarm in case of danger by judging the current temperature based on a criterion set to artificial intelligence through the Watson studio 300g, and the Watson IoT platform ( 300b) receives various sensing values from the IoT touch switch 100 or transmits and receives user information data values or control commands from the user terminal 200, and the client 300c is a sensing value and user of the Watson IoT platform 300b. It may be configured to store the information data, the control command data for each time at a certain period. The object storage 300d receives data from the client 300c to store the big data map, and the Apache Spark 300e quickly extracts profile data of a desired subject using a cloud distributed computing module, and the DB data warehouse 300f. Process and store the extracted profile data as data that can be used by the AI algorithm, and Watson Studio (300g) analyzes and learns it, and sets control commands according to the sensing value judgment criteria and judgment criteria of the cloud application 300a. It can be configured to be.

The cloud application 300a may be configured to include a service building module 301, a service interworking module 302, a service control module 303, a sensing value determination module 304, and an alarm transmission module 305.

The Watson IoT platform 300b includes a user body / emotional information receiving module 306, a location / arrival time information receiving module 307, a wireless input command receiving module 308, a wireless input command transmitting module 309, and a sensing value receiving. It may be configured to include a module 310.

The client 300c may be configured to include a Watson IoT database 311.

Object storage 300d may be configured to include big data map database 312.

Apache Spark 300e may be configured to include a cloud distributed computing module 313, a profile data extraction module 314.

DB data warehouse 300f may be configured to include profile data building module 315.

Watson studio 300g may be configured to include profile AI analysis module 316, AI control command definition module 317, and AI control command transmission module 318.

Hereinafter, the detailed structure is demonstrated.

The service building module 301 includes the Watson IoT platform 300b, the client 300c, the object storage 300d, the Apache spark 300e, the DB data warehouse 300f, and the Watson studio 300g of the IBM cloud 300. ) May be configured to execute and build according to an algorithm within the cloud application 300a.

The service interworking module 302 may be configured to interoperate services executed by the service building module 301 with each other.

The service control module 303 may transmit and control a control command by the AI control command transmission module 318 of the sensing value determination module 304, the user terminal 200, and the Watson studio 300g to each service for control. It can be configured to be.

The sensing value determination module 304 sets a criterion for the dangerous situation such as fire defined and set in the AI control command definition module 317 of the Watson studio 300g, and the AI control command transmission module 318 of the Watson studio 300g. If received through the outside of the setting criteria setting range can transmit a control command to the service control module 303, an alarm transmission command to the alarm transmission module 305.

The alarm transmission module 305 may be configured to transmit the alarm generated by the sensing value determination module 304 to the user terminal 200.

The user body / emotional information receiving module 306 receives the user body / emotional information and SNS analysis information from the user body / emotional information transmitting module 209 of the user terminal 200 and performs a service interworking module of the client application 300a. 302 may be configured to be stored in the Watson IoT database 311 of the client (300c).

The location / arrival time information receiving module 307 may receive information such as a current location, a destination, an arrival time of the user terminal 200 from the location / arrival time information transmitting module 206 of the user terminal 200. Here, the smart home may be pre-associated with each user terminal 200, and the smart home may also be associated with a plurality of user terminals 200. The destination may be a criterion for determining which smart home. Also, the location / arrival time information received by the location / arrival time information receiving module 307 may be stored in the Watson IoT database 311 of the client 300c through the service interworking module 302 of the client application 300a. It can be configured to be.

The wireless input command receiving module 308 may be configured to receive a wireless input command from the wireless input command transmitting module 202 of the user terminal 200. The wireless input command of the application 200 of the user terminal 200 is a component for remotely controlling various indoor devices. In addition, the remote control command received by the wireless input command receiving module 308 may be stored in the Watson IoT database 311 of the client 300c for each time period through the service interworking module 302 of the client application 300a. Can be configured.

The wireless input command transmitting module 309 transmits the wireless input command received from the wireless input command receiving module 308 to the wireless input command receiving module 102 of the IoT touch switch 100, and the transmitted wireless input command is transmitted to the cloud. It may be configured to be stored in the Watson IoT database 311 of the client (300c) for each time zone through the service interworking module 302 of the dungeon application (300a).

The sensing value receiving module 310 receives sensing value data such as temperature, humidity, fine dust, gas, etc. for each room from the sensing value transmitting module 109 of the IoT touch switch 100 provided in each room. The sensing value data may be configured to be stored in the Watson IoT database 311 of the client 300c through the service interworking module 302 of the client application 300a.

The Watson IoT database 311 includes a user body / emotional information receiving module 306, a location / arrival time information receiving module 307, a wireless input command receiving module 308, and a wireless input command transmitting module of the Watson IoT platform 300b. 309, all of the information from the sensing value receiving module 310 may be stored at regular intervals.

The big data map database 312 may be configured to store and store atypical data such as sensing values and unstructured data such as user body / emotional information over a long period from the Watson IoT database 311 of the client 300c. .

The cloud distributed computing module 313 may be configured to support the data data stored in the big data map database 312 of the object storage 300d so that the profile data extraction module 314 quickly extracts the profile data of the required subject. In this case, the profile data refers to data on a certain subject, and refers to extracting only data on temperature if the subject is temperature, and only data on member information, location information, and SNS information on user information.

The profile data extraction module 314 is configured to extract profile data from the big data of the big data map database 312 of the object storage 300d and deliver the profile data to the profile data building module 315 of the DB data warehouse 300f. Can be.

The profile data building module 315 may be configured to be processed and stored so that the profile AI analysis module 316 of Watson Studio 300g can use the profile data for AI analysis.

 The profile AI analysis module 316 may be configured to receive data through the profile data building module 315 of the DB data warehouse 300f and analyze and determine the result using an artificial intelligence algorithm. That is, the profile data may be analyzed to determine body / emotional information such as whether the user is tired, energetic, excited, angry, or happy.

The AI control command definition module 317 may be configured to set the definition of the current criterion analyzed and determined by the profile AI analysis module 316 or to set the control priority and the control command definition. For example, redefine the criteria such as whether the normal temperature is suitable for the criteria temperature by season, whether the fine dust concentration is suitable for the criteria concentration according to the weather, and whether the gas concentration is suitable for the criteria concentration according to the air density. Or, it may be configured to define the control command priority and control commands of the various devices and to deliver to the AI control command transmission module 318.

For example, in the case of temperature, humidity, fine dust, and gas, when gas leaks are detected, gas emissions may be the top priority. Even if indoor fine dust is sensed high, gas leakage should be performed using the automatic window switch 50.

In addition, the user may control the temperature, humidity, lighting, TV on / off or TV channel, audio music selection and playback optimized for the user according to the arrival time of the smart home. Here, the optimized environment such as the optimized temperature, humidity, and lighting of the user may create an optimized environment by referring to the current profile and the existing profile defined by the AI profile definition module 317. TV channels and audio music are TV channels or audio music that the user frequently watches for a long time, or TV channels or audio music mainly viewed in a specific body / emotional state through the user body / emotional information collection module 207 of the user terminal 200. It can be collected in a TV application or an audio application. You can create an optimization environment by referring to an existing profile but giving more weight to the current profile.

At this time, temperature, humidity, TV, audio, lighting, etc. can be controlled for each user room. That is, since there may be several users in one home, each user's room may be configured to refer to a profile divided for each user.

In addition, by referring to the profile divided by user, the user can predict the temperature and humidity of the user space in real time and reflect it in the AI control.

Each control may be defined by time and space, and may be configured by defining priority and weight of each control to be set differently.

The AI control command transmission module 318 transmits the criterion defined in the AI control command definition module 317 to the sensing value determination module 304 of the cloud application 300a so as to set a reference point or generate the generated control command. It may be configured to deliver to the service control module 303 and transmit in real time to the IoT control module 108 of the IoT touch switch 100.

2 is a flowchart of a method of operating an IBM cloud-based smart home touch switch system according to an embodiment of the present invention.

Referring to FIG. 2, the user terminal 200 accesses an IBM cloud 300 and performs a subscription (S101).

Next, the IoT touch switch 100 senses the temperature using a pre-built temperature sensor and real-time to the Watson IoT platform 300b of the IBM cloud 300. Transmit (S102).

Next, the Watson IoT platform 300b receives the temperature in real time and the Watson IoT of Cloudant 300c through the service interworking module 302 of the cloud application 300a. The database is stored in the database 311, and the Watson IoT database 311 accumulates and stores data in the big data map database 312 of the object storage 300d in the long term (S103).

Next, the profile data extraction module 314 of the Apache spark 300e extracts the profile data of the required subject from the big data map database 312 of the object storage 300d, and executes the DB data. The profile data building module 315 of the data warehouse 300f builds the profile data (S104).

Next, Watson studio 300g analyzes the profile data at regular intervals to redefine the criterion of the sensing value determination module 304 of the cloud application 300a (S105).

Next, the cloud application 300a checks whether the sensing value determination module 304 is abnormal based on the redefined criterion (S106).

Next, an alarm is generated when there is a cloud application (300a) or more, and the alarm generated by the alarm transmission module 305 is transmitted in real time to the user terminal 200 (S107).

Next, the user terminal 200 receives the alarm and outputs it (S108).

Referring to FIG. 3, the user terminal 200 accesses an IBM cloud 300 and performs a subscription (S201).

Next, the user terminal 200 transmits a wireless input command to the Watson IoT platform 300b of the IBM cloud 300 according to the user's input (S202).

Next, the Watson IoT platform 300b receives the wireless input command and transmits the wireless input command to the IoT touch switch to be controlled by the corresponding IoT touch switch 100 (S203). ).

Next, the IoT touch switch 100 receives the wireless input command of the Watson IoT platform 300b and controls the on / off switching of the lights (S204).

Next, the light switch is turned on / off (S205).

Although described with reference to the above embodiments, those skilled in the art can understand that the present invention can be variously modified and changed without departing from the spirit and scope of the invention described in the claims below. There will be.

10: lighting equipment
20: air conditioning equipment
30: humidifier
40: air freshener
50: window automatic switch
60: TV
70: audio equipment
100: IoT touch switch
101: touch input module
102: wireless input command receiving module
103: on / off switching module
104: temperature sensor
105: humidity sensor
106: fine dust sensor
107: gas detection sensor
108: IoT Control Module
109: sensing value transmission module
200: user terminal
201: command input module
202: wireless input command sending module
203: alarm receiving module
204: alarm output module
205: navigation collection module
206: location / arrival time information transmission module
207: User body / emotional information collection module
208: SNS analysis module
209: user body / emotion information transmission module
300: IBM cloud
300a: cloud application
300b: Watson IoT platform
300c: Cloudant
300d: object storage
300e: Apache spark
300f: DB data warehouse
300g: Watson studio
301: service building module
302: service interworking module
303: service control module
304: sensing value determination module
305: alarm transmission module
306: user body / emotional information receiving module
307: location / arrival time information receiving module
308: wireless input command receiving module
309: wireless input command transmission module
310: sensing value receiving module
311: Watson IoT Database
312: big data map database
313: cloud distributed computing module
314: Profile data extraction module
315: profile data building module
316: profile AI analysis module
317: AI control command definition module
318: AI control command sending module

Claims (4)

An IoT touch switch which performs on / off switching of the lighting device according to a user's touch input or a wireless input command and senses temperature in real time by using a built-in temperature sensor;
A user terminal transmitting a wireless input command for on / off switching of the IoT touch switch;
Receives a wireless input command from the user terminal and transmits an on / off switching control command of the IoT touch switch according to the received wireless input command to the IoT touch switch, and receives the temperature from the IoT touch switch in real time and received in real time Watson IoT platform that transmits a wireless control command to control the temperature based on temperature to the IoT touch switch, and cloud and object storage in which the temperature received in real time from the Watson IoT platform is stored. Abnormality based on object storage, Apache spark to extract required profile data using the temperature stored in the object storage, and DB data warehouse to build profile data and profile data Watson studio redefines the criteria IBM cloud (IBM cloud) consisting of a cloud application (Cloud application) for generating a control command and alarm generation command for determining the abnormality and controlling the temperature according to the determination result,
The Watson IoT platform,
Receiving an illumination control command from a user terminal and transmitting an illumination control command to the IoT touch switch according to the instruction;
The cloud application,
When there is an error in the result of the determination of the real-time received temperature is configured to generate an alarm in real time to the user terminal,
The IoT touch switch,
A touch input module configured to receive a touch input from a user indoors;
A wireless input receiving module for receiving a wireless input command for controlling a lighting device, an air conditioner, a humidifier, an air purifier, a window automatic switch, a TV, and an audio device from the user terminal through the IBM cloud;
An on / off switching module for switching on / off a lighting device by a touch input of the touch input module or a wireless input command received by the wireless input command receiving module;
A temperature sensor for sensing a temperature of a room;
A humidity sensor for sensing humidity in the room;
Fine dust sensor for sensing the fine dust introduced into the room;
Gas detection sensors for detecting gas leaks in kitchens or boilers;
Each air-conditioning device, humidifier, air purifier, which is provided in each room to adjust the indoor environment based on the temperature, humidity, fine dust sensor and gas sensor sensed by the temperature, humidity, fine dust, gas, respectively An IoT control module for respectively controlling a window automatic switch, a TV and an audio device;
A sensing value transmission module for transmitting the temperature, humidity, fine dust, and gas sensing values sensed by the temperature sensor, the humidity sensor, the fine dust sensor, and the gas detection sensor to the IBM cloud in real time;
The user terminal,
A command input module for receiving a command for monitoring indoor environment or a command for remotely controlling various devices from the user;
A wireless input command transmitting module configured to transmit, in real time, a wireless input command corresponding to the command received by the command input module to the IBM cloud;
An alarm receiving module configured to receive an alarm of a cloud application if it is determined that there is a danger to an indoor environment by the cloud application of the IBM cloud;
An alarm output module for outputting an alarm received by the alarm receiving module;
A navigation collection module for collecting navigation information from a navigation application provided in the user terminal;
A location / arrival time information transmission module for real-time transmission of navigation information collected by the navigation collection module to the IBM cloud;
A user body / emotional information collection module for collecting body / emotional information of the user;
An SNS analysis module for performing text mining on an SNS application installed in the user terminal to analyze and infer the current mood, emotion, and physical state of the user;
A user body / sensibility information transmission module for real-time transmission of the user's body / sensibility information collected by the user body / sensibility information collection module and the user's body / sensitivity information analyzed by the SNS analysis module to the IBM cloud,
The cloud application,
A service building module that executes and builds services according to algorithms in a cloud application such as Watson IoT platform, client, object storage, Apache Spark, DB data warehouse, and Watson studio of the IBM cloud;
A service interworking module for interlocking services by interworking services executed by the service building module;
A service control module which transmits and controls a control command by a sensing value determination module, a user terminal, and an AI control command transmission module of Watson Studio to each service;
Decision criteria for dangerous situations such as fire defined and set in the AI control command definition module of Watson Studio is received through the AI control command transmission module of Watson Studio and the control command is transmitted to the service control module when it is out of the standard setting range. A sensing value determination module configured to transmit an alarm transmission command to the alarm transmission module;
An alarm transmission module for transmitting the alarm generated by the sensing value determination module to a user terminal,
Watson IoT Platform
A user body / sensibility information receiving module for receiving user body / sensibility information and SNS analysis information from the user body / sensibility information transmitting module of the user terminal and storing the user body / sensibility information and the Watson IoT database of the client through the service interworking module of the client application;
A location / arrival time information receiving module for receiving information such as a current location, a destination, and an arrival time of the user terminal from the location / arrival time information transmitting module of the user terminal;
A wireless input command receiving module for receiving a wireless input command from a wireless input command transmitting module of the user terminal;
The wireless input command received from the wireless input command receiving module is transmitted to the wireless input command receiving module of the IoT touch switch, and the transmitted wireless input command is transmitted to the Watson Watson IoT database of the client by time zone through the service interworking module of the client application. A wireless input command transmitting module for storing;
Receive sensing value data such as temperature, humidity, fine dust, gas, etc. for each room from the sensing value transmitting module of the IoT touch switch provided in each room, and the received sensing value data is provided through the service interworking module of the client application. Including a sensing value receiving module to store in the Watson Watson database of the client,
The client,
The Watson IoT database includes a Watson IoT database for storing all the information from the user body / sensibility information receiving module, location / arrival time information receiving module, wireless input command receiving module, wireless input command transmitting module, and sensing value receiving module of the Watson IoT platform at regular intervals. and,
The object storage,
A big data map database for accumulating and storing unstructured data such as sensing values and user body / emotional information over a long period from the Watson IoT database of the client,
The Apache Spark,
A cloud distributed computing module configured to quickly extract profile data of a subject requiring a profile data extraction module from data stored in the big data map database of the object storage;
A profile data extraction module for extracting profile data from the big data of the big data map database of the object storage and transferring the profile data to the profile data building module of the DB data warehouse;
The DB data warehouse,
The profile AI analysis module of Watson Studio includes a profile data construction module for processing and storing the profile data for use in AI analysis,
The Watson studio,
A profile AI analysis module that receives data through the profile data construction module of the DB data warehouse and analyzes and judges the data using an artificial intelligence algorithm;
An AI control command definition module for setting a definition of a current determination criterion analyzed and determined by the profile AI analysis module and setting a control priority and a control command definition;
Delivering the criterion defined in the AI control command definition module to the sensing value determination module of the cloud application to set the reference point or transmitting the generated control command to the service control module to transmit in real time to the IoT control module of the IoT touch switch IBM cloud-based smart home touch switch system, characterized in that it is configured to include an AI control command sending module. delete delete delete

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