KR20190017582A - Smart plant pot, method for monitoring plant, and sever performing the method - Google Patents

Abstract

The present invention relates to a smart plant pot that is interfaced with a smart device in which a plant is planted and which drives an application associated with the planted plant. The smart plant pot includes: a plant pot case for providing a space for accommodating a cultivation soil or a culture liquid for culturing the plant therein; a first touch sensor installed on the upper part of the plant pot case so as to surround the plant pot case along the circumferential direction of the plant pot case; a second touch sensor installed at the lower portion of the plant pot case so as to surround the plant pot case along the circumference direction of the plant pot case and spaced apart from the first touch sensor by a predetermined distance at vertical intervals; and a control unit for obtaining a first touch input from a user through the first touch sensor and a second touch input from the user through the second touch sensor, performing a first operation associated with the application when the second touch input is obtained within a predetermined time after the first touch input is obtained, and performing a second operation associated with the application when either one of the first touch input or the second touch input is successively obtained within a predetermined time.

Description

TECHNICAL FIELD [0001] The present invention relates to a smart potting plant, a plant monitoring method,

The present invention relates to a smart pot, a plant monitoring method, and a server for performing the method. More particularly, the present invention relates to a smart pot, which monitors the cultivation environment of the plant where the plant is planted and cultivated or enables the interaction between the plant and the user, the behavior of the user who takes care of the plant cultivation environment and the plant through the smart pot, A plant monitoring method for recording and processing information monitored through a server linked to a flowerpot, and a server for performing the plant monitoring method in cooperation with the smart flower pot

For a plant to grow well, it is important to provide an environment suitable for plant growth. Recently, with the advent of the development of electronic technology, there have been various attempts to detect the environment in which the plant is grown, including temperature and humidity, in real time and automatically provide the optimum environment.

However, these existing attempts have focused mainly on the viewpoint of cultivating plants in farms and the like. Therefore, most of the plant cultivation technologies that combine the existing electronic technology detect whether a plant-optimized growth environment is provided. Even the more advanced technology, the environment of the plant cultivation space is controlled to be controlled by various devices in order to provide an optimized growth environment.

On the other hand, with the recent increase in the number of single-person households, workers who are unable to raise their companion animals are increasingly demanding to raise their plants as a substitute for companion animals. According to this tendency, in the field of smart plant cultivation technology, research is being conducted not only to transmit information for cultivation of plants, but also to provide a platform capable of communicating with reciprocal plants and users.

An object of the present invention is to provide a smart flower pot, a plant monitoring method, and a server for performing the same, which enable communication between a user and a plant.

Another object of the present invention is to provide a smart flower pot, a plant monitoring method, and a server for performing the same, which realize the growth environment of a plant grown in a flowerpot and the affection degree to a plant through a GUI.

Another object of the present invention is to provide a smart pot, a plant monitoring method, and a server for performing the smart pot, which performs a different operation according to each touch behavior by discriminating and sensing various touch behaviors of a user cultivated in a pot.

It is to be understood that the present invention is not limited to the above-described embodiments and that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the following claims .

According to one aspect of the present invention, there is provided a smart flower pot which is planted and is associated with a smart device for driving an application related to the plant cultivated, wherein a space for cultivating the plant or a culture medium A potted case provided; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case; A second touch sensor installed at a lower portion of the flowerpot case so as to surround the flowerpot case along the circumference of the flowerpot case and spaced apart from the first touch sensor by a predetermined interval; And acquiring a first touch input from a user through the first touch sensor, acquiring a second touch input from a user through the second touch sensor, and acquiring a second touch input from a user within a predetermined time after acquiring the first touch input, When the input is obtained, performing a first operation related to the application, and when a touch input of either the first touch input or the second touch input is successively acquired within a predetermined time, And a controller for performing the smart flower pot.

According to another aspect of the present invention, there is provided a smart flower pot that is interlocked with a smart device in which a plant is planted and an application related to the planted plant is operated, the pot flower case providing a space in which a soil or a culture medium is received; A first touch sensor and a second touch sensor provided in the flowerpot case and spaced apart from each other in the vertical direction; A communication unit for communicating with a server associated with the smart device in association with the application; And acquiring a first touch input from a user through the first touch sensor, acquiring a second touch input from a user through the second touch sensor, and acquiring a second touch input from a user within a predetermined time after acquiring the first touch input, When the input is received, transmits to the server a first message requesting recording of the execution of the stroking gesture through the communication unit, and wherein the first touch input or the second touch input is continuously transmitted within a predetermined time When acquired, transmits a second message requesting transmission of a push message regarding the application including affinity information on the plant calculated based on the stroking gesture to the smart device via the communication unit to the server Can be provided.

According to another aspect of the present invention, there is provided a method for controlling a flowerpot, comprising: a first touch sensor installed on an upper part of a flowerpot case to surround the flowerpot case along a circumferential direction of the flowerpot case; A communication unit for communicating with the smart pot and the smart device, the smart pot including a second touch sensor which is installed to surround the case and is spaced apart from the first touch sensor by a predetermined interval in the vertical direction; A memory for recording information; And when a second touch input is obtained from the second touch sensor within a predetermined time after the first touch input is obtained from the first touch sensor of the smart flower pot, The first touch input or the second touch input is successively obtained within a predetermined time, and the first touch input or the second touch input is successively obtained within a predetermined time Receives via the communication unit a second message requesting transmission of a push message relating to the application including affinity information for the plant calculated based on the stroking gesture to the smart device, And a controller for requesting the smart device to provide the push message to the user in response to the message A bur can be provided.

According to still another aspect of the present invention, there is provided a method of controlling a flowerpot comprising a first touch sensor installed on an upper part of a flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case, A communication part for communicating with at least one of a smart flower pot or a server, which is installed to surround the flower pot case and includes a second touch sensor spaced apart from the first touch sensor by a predetermined interval in an up / down direction; An output unit for displaying information; And when a second touch input is obtained from the second touch sensor within a predetermined time after the first touch input is obtained from the first touch sensor of the smart flower pot, When the first touch input or the second touch acquired second touch input is successively acquired within a predetermined time, the stroking gesture is applied to the stroking gesture Receiving, via the communication unit, a second message requesting transmission of a push message relating to the application, the information including affinity information for the plant calculated based on the first message; and providing the push message to the user according to the second message A control unit, and a smart device may be provided.

According to another aspect of the present invention, there is provided a potting case for providing a space in which a cultivation soil or a culture liquid for cultivating a plant is received; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor which is spaced apart from the first touch sensor by a predetermined distance in a vertical interval, the method comprising: acquiring a first touch input from the user through the first touch sensor ; Obtaining a second touch input from the user through the second touch sensor; Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And performing a second operation related to the application when any one of the first touch input and the second touch input is successively acquired within a predetermined time period have.

According to another aspect of the present invention, there is provided a potting case for providing a space in which a cultivation soil or a culture liquid for cultivating a plant is received; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor which is spaced apart from the first touch sensor by a predetermined distance in the vertical direction, the method comprising the steps of: receiving from a user received through the first touch sensor Obtaining a first touch input of the touch screen; Obtaining a second touch input from a user received via the second touch sensor; Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And performing a second operation related to the application when any one of the first touch input and the second touch input is successively acquired within a predetermined time period have.

It is to be understood that the solution of the problem of the present invention is not limited to the above-mentioned solutions, and the solutions which are not mentioned can be clearly understood by those skilled in the art to which the present invention belongs It will be possible.

According to the present invention, a user can interact with plants by sensing the interaction between a user and a plant and outputting feedback on the interaction.

In addition, according to the present invention, the user can intuitively inform the user of the plant's growth environment and the user's affection toward the plant by implementing the growth environment of the plant grown in the flowerpot and the affection degree to the plant with the GUI.

In addition, according to the present invention, various touch behaviors of a user cultivated in a flowerpot are distinguished and detected, and other actions are performed according to each touch behavior, thereby measuring the degree of affection of the user to the plant and informing the user.

It is to be understood that the present invention is not limited to the above-described embodiments and that various changes and modifications may be made without departing from the spirit and scope of the present invention as defined by the following claims .

1 is a block diagram of a plant monitoring system according to an embodiment of the present invention.
2 is a block diagram of the configuration of a smart flower pot according to an embodiment of the present invention.
3 is a perspective view of a Smart Flower pot according to an embodiment of the present invention.
4 is a block diagram of a server according to an embodiment of the present invention.
5 is a block diagram of a configuration of a smart device according to an embodiment of the present invention.
6 shows a screen of a plant monitoring application according to an embodiment of the present invention.
FIG. 7 illustrates graphical objects displayed on a smart device according to an exemplary embodiment of the present invention.
8 is a flowchart illustrating a method of binding a smart flower pot and a smart device by a server in a plant monitoring system according to an embodiment of the present invention.
9 is a table of operations of an output unit according to environment information, predetermined criteria, status information, and status information according to an embodiment of the present invention.
10 is a table for obtaining status information using environment information and predetermined criteria according to an embodiment of the present invention, and determining the operation of the output unit.
11 is a flowchart illustrating a method for obtaining a status information determination criterion set for each plant species according to an embodiment of the present invention.
12 is a flowchart illustrating a method of acquiring state information according to an embodiment of the present invention.
Figure 13 relates to a stroking gesture in a smart pot according to an embodiment of the present invention.
FIG. 14 is a table for recording strokes according to an embodiment of the present invention. FIG.
15 is a diagram of a smart gesture in a smart pot according to an embodiment of the present invention.
16 illustrates the operation of a smart flower pot displaying status information according to an embodiment of the present invention.
FIG. 17 illustrates the response of a smart flower pot according to a stroking gesture in a smart pot according to an embodiment of the present invention.
18 illustrates the smart pot pollution response according to a smart gesture in a smart pot according to an embodiment of the present invention.
19 is a flowchart illustrating a method of displaying state information according to an embodiment of the present invention as a display attribute of an aura object.
FIG. 20 is a table of state information and display attributes of an aura object corresponding thereto according to an embodiment of the present invention.
FIG. 21 is a flowchart illustrating a method of displaying a display attribute of a character object according to a strobe record according to an embodiment of the present invention.
FIG. 22 is a diagram illustrating a growth attribute of a display attribute of a character object according to an exemplary embodiment of the present invention.
23 is a flowchart of a method of providing a push message in a predetermined conditional satisfaction according to an embodiment of the present invention.
24 is a diagram of a screen of a smart device on which a push message according to status information change is displayed.
25 is a diagram of a screen of a smart device in which a push message according to a change of a display attribute of a character object is displayed.
26 is a diagram of a screen of a smart device in which a push message according to a smart gesture is displayed.
FIG. 27 is a flowchart illustrating a method of monitoring status information obtained based on environment information according to an embodiment of the present invention through an aura object.
FIG. 28 is a flowchart illustrating a method of monitoring a typing record obtained on the basis of a stroked gesture through a character object according to an embodiment of the present invention.
FIG. 29 is a diagram of a timeline in which a strobe record according to an embodiment of the present invention is displayed. FIG.
30 is a diagram illustrating a screen for displaying one or more character objects and aura objects in one smart device according to an exemplary embodiment of the present invention.

Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the inventive concept. Other embodiments falling within the scope of the inventive concept may readily be suggested, but are also considered to be within the scope of the present invention.

The same reference numerals are used to designate the same components in the same reference numerals in the drawings of the embodiments.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of known configurations or functions related to the present invention will be omitted when it is determined that the gist of the present invention may be blurred.

According to one aspect of the present invention, a Smart Flowerpot interlocked with a smart device for planting plants and driving an application related to the cultivated plant includes a space in which a cultivated soil or a culture medium for culturing the plant is stored A potted case provided; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case; A second touch sensor installed at a lower portion of the flowerpot case so as to surround the flowerpot case along the circumference of the flowerpot case and spaced apart from the first touch sensor by a predetermined interval; And acquiring a first touch input from a user through the first touch sensor, acquiring a second touch input from a user through the second touch sensor, and acquiring a second touch input from a user within a predetermined time after acquiring the first touch input, When the input is obtained, performing a first operation related to the application, and when a touch input of either the first touch input or the second touch input is successively acquired within a predetermined time, And a control unit for controlling the display unit.

In some embodiments of the present invention, the smart flowerpot further includes a communication unit for communicating with the smart device and at least one of the servers associated with the smart device with respect to the application, wherein the first operation is performed by the control unit The control unit may transmit a second message related to the application different from the first message through the communication unit, and the second operation may transmit the second message related to the application through the communication unit.

According to another aspect of the present invention, there is provided a Smart Flowerpot interlocked with a smart device for plant-planting and driving an application related to the planted plant, comprising: a potting case for providing a space in which a soil or a culture medium is received; A first touch sensor and a second touch sensor provided in the flowerpot case and spaced apart from each other in the vertical direction; A communication unit for communicating with a server associated with the smart device in association with the application; And acquiring a first touch input from a user through the first touch sensor, acquiring a second touch input from a user through the second touch sensor, and acquiring a second touch input from a user within a predetermined time after acquiring the first touch input, When the input is received, transmits to the server a first message requesting recording of the execution of the stroking gesture through the communication unit, and wherein the first touch input or the second touch input is continuously transmitted within a predetermined time When acquired, transmits to the server a second message requesting transmission of a push message relating to the application, the information including affinity information for the plant calculated based on the stroking gesture to the smart device via the communication unit .

The pollen case is provided with the first touch sensor above the second touch sensor, and the pollen case has a circumference of a portion where the first touch sensor is installed, It may be shorter than the circumference.

The smart flowerpot further includes an illuminance sensor, wherein the circumference of the flowerpot case is lower than that of the upper portion, and the illuminance sensor is disposed in the flowerpot case having a larger circumference than the upper portion of the flowerpot case As shown in FIG.

Wherein the first touch sensor and the second touch sensor are installed in the flowerpot case so as to surround only a part of the entire circumference of the flowerpot case, And the second area in which the flowerpot case is not surrounded by the second touch sensor at a part where the second touch sensor is installed are arranged in the same direction when viewed from the top of the flowerpot case Can be located.

The smart flower pot may further include an illuminance sensor whose light receiving direction is directed in the same direction.

The SmartPower may further include an output unit that outputs a visual signal, the light output direction of which is oriented in the same direction.

According to another aspect of the present invention, a server includes a first touch sensor installed on an upper part of a flowerpot case to surround the flowerpot case along a circumferential direction of the flowerpot case, and a second touch sensor installed on a lower portion of the flowerpot case along a circumferential direction of the flowerpot case And a second touch sensor installed to surround the flowerpot case and spaced apart from the first touch sensor by a predetermined interval in a vertical interval; A memory for recording information; And when a second touch input is obtained from the second touch sensor within a predetermined time after the first touch input is obtained from the first touch sensor of the smart flower pot, The first touch input or the second touch input is successively obtained within a predetermined time, and the first touch input or the second touch input is successively obtained within a predetermined time Receives via the communication unit a second message requesting transmission of a push message relating to the application including affinity information for the plant calculated based on the stroking gesture to the smart device, And a controller for requesting the smart device to provide the push message to the user in response to the message The.

According to another aspect of the present invention, there is provided a smart device including a first touch sensor installed on an upper part of a flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case, and a second touch sensor installed on a lower portion of the flowerpot case, A communication unit communicating with at least one of a smart flowerpot or a server including a second touch sensor installed to surround the flowerpot case and spaced apart from the first touch sensor by a predetermined interval in a vertical interval; An output unit for displaying information; And when a second touch input is obtained from the second touch sensor within a predetermined time after the first touch input is obtained from the first touch sensor of the smart flower pot, When the first touch input or the second touch acquired second touch input is successively acquired within a predetermined time, the stroking gesture is applied to the stroking gesture Receiving, via the communication unit, a second message requesting transmission of a push message relating to the application, the information including affinity information for the plant calculated based on the first message; and providing the push message to the user according to the second message And a control unit.

According to another aspect of the present invention, there is provided a potting case for providing a space in which a cultivation soil or a culture liquid for cultivating a plant is received; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor which is spaced apart from the first touch sensor by a predetermined distance in a vertical interval, the method comprising: acquiring a first touch input from the user through the first touch sensor; ; Obtaining a second touch input from the user through the second touch sensor; Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And performing a second operation related to the application when any one of the first touch input or the second touch input is successively acquired within a predetermined time.

According to another aspect of the present invention, there is provided a potting case for providing a space in which a cultivation soil or a culture liquid for cultivating a plant is received; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor which is spaced apart from the first touch sensor by a predetermined distance at an upper and a lower distance, the plant monitoring method being performed by a server interlocked with a smart flower pot, Obtaining a first touch input of the touch screen; Obtaining a second touch input from a user received via the second touch sensor; Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And performing a second operation related to the application when any one of the first touch input or the second touch input is successively acquired within a predetermined time.

According to another aspect of the present invention, there is provided a smart pot and a plant application, wherein the application reflects a user's affection for the plant and a first graphical object reflecting the cultivation environment of the plant Displaying a second graphic object to be displayed on the smart flower pot, the plant monitoring method being performed by a server interlocked with a smart device for driving the environment of the plant cultivation environment detected by the environmental sensor provided in the smart flower pot, Receiving information; Receiving touch information sensed by a touch sensor provided in the smart flower pot from the smart pot flower; Obtaining a display attribute of the first graphic object based on the environment information; Obtaining a display attribute of the second graphic object based on the touch information; And transmitting a display attribute of the first graphic object and a display attribute of the second graphic object such that the smart device outputs a graphic object related to the plant.

The first graphic object may be an aura object displayed in the background of the second graphic object, and the second graphic object may be a character object.

The environmental information may include at least one of temperature information, brightness information, and water level information.

The display attribute of the aura object includes at least one type, and the type can be calculated based on the type of environmental information satisfying at least one predetermined criterion corresponding to the environment information.

The display attribute of the aura object includes at least one level, and the level can be calculated based on the number of environment information satisfying a predetermined criterion among the environment information.

The predetermined criteria may be set differently for each type of plant.

The display attribute of the character object includes a growth attribute, the growth attribute is calculated according to the affinity, and the size of the character object may be increased when the growth attribute is increased.

The growth attribute may increase when the affinity is equal to or greater than a first predetermined affinity or when the affinity is equal to or greater than a second predetermined affinity greater than a first predetermined affinity.

The plant monitoring method may further include requesting the smart device to provide a push message to the user when the display property of the aura object is changed or when the growth attribute of the character object is changed.

The growth attribute may increase when the affinity is equal to or greater than a first predetermined affinity or when the affinity is equal to or greater than a second predetermined affinity greater than a first predetermined affinity.

In some embodiments, the method for monitoring a plant according to an embodiment of the present invention may further include the step of providing a push message to the user when the display property of the aura object is changed or when the growth attribute of the character object is changed, To the mobile terminal.

 According to a further aspect of the present invention there is provided an application for a plant in which a plant is cultivated and the application comprises a first graphical object reflecting the cultivation environment of the plant and a second graphic reflecting the user's affection for the plant The smart pot that works in conjunction with a smart device that drives an object - includes a touch sensor that senses touch information; An environmental information sensor for sensing environment information on the cultivation environment of the plant; A communication unit for communicating with at least one of the smart device and the server; And the server transmits the environment information to the server so that the server can transmit the display attribute of the first graphic object obtained by acquiring the display attribute of the first graphic object based on the environment information to the smart device, A controller for transmitting the touch information to the server so that the server can transmit the display attribute of the second graphic object obtained by acquiring the display attribute of the second graphic object based on the touch information to the smart device; . ≪ / RTI >

According to another aspect of the present invention there is provided a smart flowerpot in which a plant is grown and an application on said plant, said application reflecting a first graphical object reflecting the cultivation environment of said plant and a user's affection for said plant Displaying a first graphical object and a second graphical object, the communication device communicating with at least one of the smart flower pot and the smart device; And a control unit for receiving environment information on the plant sensed by the environmental sensor provided in the smart flower pot from the smart pot through the communication unit, and receiving, from the smart pot through the communication unit, a touch sensed by the touch sensor Acquiring a display attribute of the first graphic object based on the environment information, acquiring a display attribute of the second graphic object based on the touch information, and receiving, via the communication unit, And a controller for transmitting a display attribute of the first graphic object and a display attribute of the second graphic object to output a graphic object related to the plant.

According to another aspect of the present invention, there is provided an application related to a plant, in association with a smart flowerpot and a server in which a plant is grown, the application comprising: a first graphic object reflecting the cultivation environment of the plant; A second graphic object that reflects the first graphic object, the smart device driving the smart device comprises: an output unit displaying the graphic object; A communication unit for communicating with at least one of the smart flower pot and the server; And a display attribute of the first graphic object obtained on the basis of environment information of the plant detected by the environment sensor included in the smart flower pot through the communication unit from the server, A display attribute of the second graphic object obtained based on the touch information sensed by the touch sensor is received from the server, and a display attribute of the first graphic object and a display attribute of the second graphic object And a control unit for outputting the control signal.

1. Plant Monitoring System (1000)

Hereinafter, a plant monitoring system 1000 according to an embodiment disclosed by the present invention will be described.

1.1. Outline of plant monitoring system (1000)

The plant monitoring system 1000 according to an embodiment of the present invention collects information on the cultivation environment of a plant cultivated in a flowerpot and information on the degree of affection the user has to the plant and provides the collected information to the user, And is a system that helps plants grow properly.

Specifically, the plant monitoring system 1000 senses information on the cultivation environment provided to the plant including the temperature and the water level, judges the state of the plant and reports the result to the user so that the user can induce the plant to grow properly .

Also, the degree of affinity of the user with respect to the plant can be calculated based on the touch operation or the like of the smart pot 100 of the user, and the calculated degree of affinity can be graphically outputted, thereby enabling the user to interact with the plant.

Before describing the present invention in more detail, some key terms used throughout the specification will be briefly defined.

The environmental information is information on the cultivation environment of the plant cultivated in the smart pot 100. For example, the environmental information may include information on temperature, humidity, water level, brightness, and the like. For a more detailed description of environmental information, see 1.3. Configuration items of smart pot (100) and 3.2.1. Environmental information items, and the like.

The status information is information on the condition of the plant such as the condition and necessity of the plant. For example, the state information may include a hot state, a cold state, a water shortage state, and the like. Such status information can be determined based on environmental information. For status information, see 3.2.2. Describe in more detail the status information item.

The touch information is information about the touch of the user to the plant or smart pot 100 planted in the smart pot 100. The touch information can be obtained through the touch sensor 120 provided in the SmartPot 100. For example, the touch information may include information on a portion where the smart pot 100 is touched, a touched time, a touched area, and the like. Based on the touch information, a stroked gesture, a smart gesture, and the like can be sensed. For related contents, see 3.3.1. Stuttering gestures, 3.3.2. Describe it in more detail in the Smart Gestures section.

1.2. Composition of plant monitoring system (1000)

Hereinafter, the configuration of the plant monitoring system 1000 will be described.

1 is a block diagram of a plant monitoring system 1000 according to an embodiment of the present invention.

Referring to FIG. 1, a plant monitoring system 1000 according to an embodiment of the present invention may include a smart pot 100, a server 200, and a smart device 300. Each component can be linked directly or indirectly through the network.

1 shows that the plant monitoring system 1000 includes only one smart pot 100, a server 200 and a smart device 300, but in contrast to the smart pot 100 in the plant monitoring system 1000, The server 200, and the smart device 300 may be a plurality of devices. For example, the plant monitoring system 1000 may include one server 200 and a plurality of smart pots 100 and smart devices 300 linked thereto.

Here, the SmartPower 100 senses information about the environment (environment information) provided to the plant cultivated therein and the touch operation of the user who touches the SmartPower 100. The server 200 may receive environmental information and information on the sensed touch operation from the smart pot 100. [ In addition, the server 200 may store the received information, process the received information, and calculate necessary information. The smart device 300 may receive information related to the smart pot 100 or plant from the smart pot 100 or the server 200 and output it. The plant monitoring system (1000) implements GUI of the user's affection for the plant growth environment and the plants grown in the smart pot (100), thereby intuitively informing the user of the user's affection for the plant growth environment and plants .

More specifically, the smart pot 100 may include a pollen case 110. Plants may be planted in the flowerpot case 110. The smart pot 100 may also include various environmental sensors. The smart pot 100 can sense information about the environment in which the plant is grown through various environmental sensors. In addition, the smart pot 100 may include a sensor for sensing the degree of affinity of the user with the plant. The sensor for sensing the degree of affinity may include a touch sensor 120. The smart pot 100 may sense various actions performed as the user touches the smart pot 100 through the touch sensor 120. The smart pot 100 may also include an output unit 150. The smart flower pot 100 can inform the user of the environment and touch information through the output unit 150. [ Also, the smart pot 100 may include a communication unit 160. The communication unit 160 may communicate with the server 200 or the smart device 300. The smart flower pot 100 may transmit the information about the environment and the touch information to the server 200 or the smart device 300. In addition, the smart pot 100 may include a control unit 140 for receiving information from the sensor and controlling the communication unit 160.

The server 200 may include a communication unit 210. The server 200 can communicate with the smart pot 100 and the smart device 300 through the communication unit 210. [ The server 200 can receive information on the environment in which plants are grown from the smart pots 100 through the communication unit 210 and information on the degree of affection of the user to the plant. In addition, the server 200 may transmit information, such as a display attribute of the graphic object, to the smart device 300 through the communication unit 210. The server 200 may also include a memory 220. The server 200 may store information received from the smart flower pot 100 through the memory 220. In addition, the server 200 may include a controller 230. The server 200 can determine the display attribute of the graphic object to be displayed on the smart device 300 through the control unit 230. [

The smart device 300 may include a communication unit 310. The smart device 300 can communicate with the server 200 or the smart pot 100 via the communication unit 310 and can transmit and receive various information. The smart device 300 may also include an output 330. The smart device 300 may display the graphic object through the output unit 330. [ In addition, the smart device 300 may include an input unit 320. The smart device 300 may receive the input of the user through the input unit 320.

1.3. Configuration of smart pot (100)

Hereinafter, the smart pot 100, which is a component of the plant monitoring system 1000, will be described in detail with reference to its configuration.

2 is a block diagram of a configuration of a smart pot 100 associated with some embodiments of the present invention.

2, the smart pot 100 may include a pollen case 110, a touch sensor 120, an environmental information sensor 130, a control unit 140, an output unit 150, and a communication unit 160 have. On the other hand, the SmartPower 100 does not necessarily include all of the components shown in FIG. 2 or only the components shown in FIG. For example, in addition to the components shown in FIG. 2, the SmartPower 100 may include a power source (not shown) for supplying power to the SmartPower 100, a voice recognition unit (not shown) ), And the like.

Specifically, the pollen case 110 can provide a space where plants are planted. Accordingly, the plant can be planted in the pot case 110 and the plant can be grown in the smart pot 100.

Plants that are grown in potted case 110 can be plants grown in conventional soils or hydroponically grown plants.

The pollen case 110 may include an empty space therein, such as a flower pot in which plants are planted. The inner space may contain a soil or a culture medium for hydroponics to be a base on which plants grow. Plants may be grown in or on the soil or culture medium. If necessary, the inner space may be provided with a culture liquid or a water reservoir capable of containing water.

The pollen case 110 may be provided in various forms. For example, the upper portion of the flowerpot case 110 may have a conical shape in which the diameter of the upper end portion is relatively small and the diameter of the end face is increased while descending downward. The lower portion of the conical flower pot case 110 having the largest cross section can provide a space in which the components of the smart pot 100 are installed. A power supply unit (not shown), an output unit 150, a control unit 140, and the like may be provided below the flowerpot case 110. However, the shape of the pollen case 110 is not limited to the above-described embodiment.

The pollen case 110 may be provided in various materials. For example, the pollen case 110 may be made of a translucent material. In this case, the inside of the flowerpot case 110 can be confirmed from the outside through the translucent flowerpot case 110. For example, the appearance of all or part of the plants cultivated in the smart pot 100 may be appreciated from the outside. Or when the output unit 150 is located inside the screen case, the operation of the output unit 150 to display the status information and the like can be confirmed from outside the screen case.

The touch sensor 120 may be a sensor for receiving a touch input. Herein, the touch input may mean a touch of a user to a plant or smart pot 100.

The touch sensor 120 may sense information such as a position at which the touch input is sensed, an area sensed by the touch input, and a time at which the touch input is sustained.

The user can perform various gestures by touching the touch sensor 120. [ Here, the distinction of the gesture can be determined by the touch information (touch position, touch area, touch time, etc.) sensed by the touch sensor 120. [

For example, the touch sensor 120 senses a touch input from the touch sensor 120 located above the flowerpot case 110 and senses a touch input from the touch sensor 120 located below the flowerpot case 110 . The control unit 140 can recognize the touch input as a 'stroked gesture'.

In another example, the touch sensor 120 may sense successive discrete touch inputs that are input within a predetermined time interval. The control unit 140 can recognize the touch input as a 'smart gesture'.

In another example, the touch sensor 120 may sense a touch input in an area over a predetermined area. The control unit 140 can recognize the touch input as a 'wrapping gesture'.

In addition to the above-described examples, the touch sensor 120 can sense various types of touch input, and the control unit 140 can distinguish the touch input. The stroking gestures and clever gestures are discussed in more detail below.

The smart pot 100 may include one or more touch sensors 120. When one touch sensor 120 is provided, the touch sensor 120 may be in the form of a single plate.

The arrangement of the touch sensor 120 may be various.

The touch sensor 120 may be disposed in the plant itself, but may be installed in the flowerpot case 110. More preferably, the touch sensor 120 may be installed on the outer surface of the flowerpot case 110. However, the position of the touch sensor 120 is not limited to the outer surface of the pollen case 110, but may be provided on the inner surface of the pollen case 110 or inside the pollen case 110. For example, the touch sensor 120 may be installed to surround the pollen case 110 along the circumferential direction of the pollen case 110 on the outer surface of the pollen case 110.

In the case where the touch sensor 120 is provided, the touch sensor 120 may be installed so as to cover all or most of the outer surface of the pollen case 110. When there are a plurality of touch sensors 120, the touch sensors 120 may be installed apart from each other. One touch sensor 120 may be installed while enclosing the upper area of the flowerpot case 110 and the other touch sensor 120 may be installed while enclosing the lower area of the flowerpot case 110. One specific embodiment of the arrangement of the touch sensor 120 will be described later.

The types of the touch sensor 120 may be various. An electrostatic, pressure sensitive, infrared or surface ultrasonic type touch sensor 120 widely used in the related art can be used as the touch sensor 120 in the present invention and a configuration capable of sensing the user's touch The touch sensor 120 of the present invention can be used.

The environmental information sensor 130 can sense information about the smart pot 100 and the environment around the plant. The information about the environment refers to information collected to confirm that the plant is provided with an environment suitable for planting. The information on the environment is hereinafter referred to as " environment information ".

The environment information sensor 130 can continuously collect environment information at a constant time interval. If the predetermined time interval is very short, the environment information sensor 130 can sense environment information substantially in real time.

The environmental information sensor 130 can sense various kinds of environmental information. The environmental information sensor 130 may include various types of environmental information sensors 130 for sensing various kinds of environmental information. For example, the environmental information may be temperature information, brightness information, or level information. Accordingly, the environmental information sensor 130 may include the temperature sensor 131, the illuminance sensor 132, the water level sensor 133, and the like.

As an example of each environmental information, the temperature information may indicate a temperature around the plant or smart pot 100. [ The temperature information may be used to determine if the ambient temperature is within a temperature range suitable for plant growth. The temperature information can be measured from the temperature sensor 131 and transmitted to the controller 140.

The brightness information may be information about the light irradiated by the plant or smart pot 100. The brightness information is information on how much the plant receives light for plant growth and photosynthesis. For example, the brightness information may include information on the intensity of light, the amount of light, the wavelength of light, or the irradiation time of light. The luminous intensity information can be measured from the light sensor and transmitted to the control unit 140.

The water level information may be information on how much water or culture liquid is given to the plant. The water level information may be, for example, information on the height, volume, or mass of the water or the culture liquid contained in the water bucket. The water level information can be measured from the water level sensor 133 and transmitted to the control unit 140.

The environmental information according to the present invention may include all the information that needs to be monitored for plant cultivation such as humidity, oxygen concentration in the air, carbon dioxide concentration, and the like in addition to the above-described embodiments of the environmental information.

The location where the environmental information sensor 130 is installed may vary. The environment information sensor 130 may have various installation positions depending on environment information to be measured.

For example, the position of the water level sensor 133 will be described. For example, the water level sensor 133 can be installed inside the water bottle. The water level sensor 133 may be installed long in the height direction of the water bottle from the bottom to the top of the water bottle. An embodiment in which the water level sensor 133 is disposed will be described later in more detail with reference to FIG.

Or the position where the light intensity sensor 132 is installed may be a position effective for receiving light. For example, the illuminance sensor 132 may be installed on the outer surface of the pollen case 110. The illuminance sensor 132 may also be provided at a suitable distance so as not to disturb the reception of light by the plant being cultivated. An embodiment in which the illuminance sensor 132 is disposed will be described later in more detail with reference to FIG.

The control unit 140 controls the overall operation of the SmartPot 100. The control unit 140 may be implemented by a computer or the like in accordance with hardware, software, or a combination thereof so as to perform calculation and processing of various information. It may be a processor that stores and processes data in terms of hardware, and may be provided in a form of a program or a code that drives a circuit in software. For example, the control unit 140 can receive information sensed by the touch sensor 120 and the environment information sensor 130 in the form of data, and the control unit 140 can process the data as needed. The control unit 140 may encode the data according to an appropriate protocol and store the data in its own memory (not shown) or transmit it to the server 200 or the smart device 300 through the communication unit 160. The control unit 140 may call the data stored in the self-memory (not shown) and decode the data to interpret necessary information.

The output unit 150 outputs a video / audio signal reflecting environment information and status information, or outputs a response to a user's touch input.

The output unit 150 may be implemented in the form of a video output unit or an audio output unit.

The video output unit may use various presentation methods for effectively displaying information to the user. For example, the output unit 150 may provide information to the user in various manners, such as text, still images, moving images, blinking lights or light colors. As will be described later, the output unit 150 may display light of a predetermined color corresponding to the status information, and may display predetermined blinking of light corresponding to the touch information.

The output unit 150 in the form of a video output unit may include various configurations for this purpose. For example, the output unit 150 may include a light emitting diode (LED). Or output unit 150 may be a liquid crystal display, a thin film transistor-liquid crystal display, an organic light-emitting diode, a flexible display, a three- (3D display).

The voice output unit may be provided in the form of a speaker or the like for outputting a voice signal.

The communication unit 160 communicates with the communication units 210 and 310 of the server 200 or the smart device 300 to enable information exchange. The communication unit 160 may communicate with the server 200 or the smart device 300 by wire or wirelessly, but may be implemented by wireless communication. The communication unit 160 may transmit the environment information and the touch information obtained through the sensor provided in the smart pot 100 to the server 200 or the smart device 300. [ The communication unit 160 can receive information including plant species information from the server 200 or the electronic equipment.

The information exchanged may be in various formats. For example, the server 200 or the smart device 300 may be in the form of digital data in which the information is encoded by a protocol that can be interpreted / processed.

Hereinafter, the shape and arrangement of the touch sensor 120, the water level sensor 133, and the illuminance sensor 132 will be described in more detail with reference to FIG. It should be noted, however, that the description of the specific arrangement and the like of each sensor with reference to FIG. 3 is only an embodiment of the present invention, and therefore, the arrangement of each sensor is not limited to the embodiment described below.

FIG. 3 is a diagram depicting one embodiment of smart pot 100 in accordance with one embodiment of the present invention.

First, the touch sensor 120 will be described.

Referring to FIG. 3, the touch sensor 120 may be installed on the outer surface of the flowerpot case 110 along the circumferential direction of the flowerpot case 110. For example, the touch sensor 120 may be installed to surround the entire circumference of the flowerpot case 110.

As another example, the touch sensor 120 may be installed with only a part of the periphery of the pollen case 110, and the other part of the periphery may be open without being wrapped. In this case, when the plurality of touch sensors 120 are provided, the installation direction of the open area of each touch sensor 120 may be the same direction. Only a part of the touch sensors 120 of the plurality of touch sensors 120 may be installed with the open area. The open area may be provided at least one at the same height as the pollen case 110. The provision of the open area may take into consideration a correlation with other sensors installed in the flowerpot case 110.

A water level sensor 133, an ambient light sensor 132, and an output unit 150 may be installed in the open area.

For example, the open area may be a part where the illuminance sensor 132 is irradiated with light. In one area where the touch sensor 120 does not surround the pot case 110, an illuminance sensor 132 may be provided. The angle formed by both ends of the touch sensor 120 when the touch sensor 120 does not surround the pot case 110 may be determined in consideration of the operation of the illuminance sensor. The angle between both ends can be determined in consideration of the light receiving angle of the illuminance sensor. The angle formed between the both ends may be determined so as to correspond to the optimum receiving angle of the illuminance sensor. The specific arrangement of the illuminance sensor will be described later.

As another example, the open area may be the steering direction of the output unit 150. An output unit 150 may be provided in the open area. The angle formed by both ends of the touch sensor 120 in the open region can be determined in consideration of the operation of the output section. The angle between the two ends may be determined in consideration of the fact that the display operation of the output unit is confirmed outside the smart pot 100. The output information of the output unit can be confirmed outside the smart pot 100 through the open area. The output unit may be installed on the outer surface of the flowerpot case 110 in the open area or may be installed in the inner space of the flowerpot case 110 in the open area.

As another example, the open area may provide a space in which the water level sensor is installed. The angle formed by both ends of the touch sensor 120 in the open area may be determined in consideration of the size of the water level sensor. The specific arrangement of the water level sensor will be described later.

When there are a plurality of open regions, the illuminance sensor, the output portion, and the water level sensor may be provided in the same open region or may be provided in separate open regions in consideration of mutual interference between the illuminance sensor, the output portion, and the water level sensor .

The touch sensor 120 may include a first touch sensor 121 and a second touch sensor 122. The first touch sensor 121 may be installed along the circumference of the flowerpot case 110 at an upper portion of the flowerpot case 110. The second touch sensor 122 may be installed along the circumferential direction of the flowerpot case 110 below the flowerpot case 110. Accordingly, the touch sensor 120 can receive an input for touching the upper part of the flowerpot case 110 and an input for touching the lower part separately.

The first touch sensor 121 and the second touch sensor 122 may be spaced apart from each other by a predetermined interval at upper and lower intervals. The predetermined upper and lower intervals may be determined based on the touch position of the user, the size of the touch sensor 120, or the size of the touch sensor 120 so that the user can effectively recognize various kinds of gestures such as stroking the pot from top to bottom, Type and the like.

For example, when the strobe gesture is recognized when the second touch input is obtained after a predetermined time after acquiring the first touch input, the predetermined time is short if the up / down interval is short, and the predetermined time The upper and lower intervals and the predetermined time may be set to be longer.

With the above arrangement, the touch sensor 120 can receive touch information used for recognizing various touch operations such as the above-mentioned stroking gesture and smart gesture.

Next, the water level sensor 133 will be described. Referring to FIG. 3, the water level sensor 133 may be in the form of a long rod, for example. The long bar-shaped water level sensor 133 can be installed in the height direction of the water bottle. The water level sensor 133 can measure the level of the culture liquid or water contained in the water bucket.

The water level sensor 133 may be one type of capacitor in which two long electrodes are arranged in parallel. The water level sensor 133 may be a sensor for measuring the water level using a change in the permittivity between the electrodes depending on the level of the liquid contained in the water bucket.

Or the water level sensor 133 may include an electrode row arranged in the longitudinal direction of the support on the long bar type support. The electrode row may have a configuration in which a plurality of electrodes are arranged in a row in the longitudinal direction of the support. The water level sensor 133 may include at least two electrode rows arranged in parallel with each other. In the case where two electrodes positioned at the height of the liquid level of the culture medium are connected to each other via the culture medium, the level sensor 133 may be configured to measure the level of the culture liquid by measuring the flow of minute current or the change of the resistance value.

Next, the illuminance sensor 132 will be described. The illuminance sensor 132 may be installed at a position where the illuminance sensor 132 can effectively measure the quantity of light. For example, the illuminance sensor 132 may be installed on the outer surface of the flowerpot case 110. The illuminance sensor 132 may be installed such that the measurement part faces outside of the flowerpot.

In addition, the illuminance sensor 132 can be located at a position where the effect of blocking the light by the leaves of plants planted in the flowerpot case 110 can be minimized. The illuminance sensor 132 may be located at a position where the diameter of the pollen case 110 is the largest. 3, the illuminance sensor 132 may be installed below the flowerpot case 110 having the largest diameter of the flowerpot case 110 and on the outer surface of the flowerpot case 110.

The illuminance sensor 132 may be disposed in consideration of the position of the touch sensor 120 installed on the outer surface of the flowerpot case 110. For example, the touch sensor 120 and the illuminance sensor 132 may be spaced apart from each other so that the sensing operation of the illuminance sensor 132 is not disturbed when the touch input is performed. Referring to FIG. 3, the illuminance sensor 132 may be installed on the outer surface of the flowerpot case 110 in a region where the touch sensor 120 is opened without being wrapped.

1.4. The configuration of the server 200

Hereinafter, the configuration of the server 200 will be described in detail.

4 is a block diagram of a configuration of a server 200 according to an embodiment of the present invention. Referring to FIG. 4, the server 200 may include a communication unit 210, a memory 220, and a controller 230. The components shown in FIG. 4 list components that can typically be included in the server 200. Accordingly, it is needless to say that the server 200 including more or fewer components than those shown in the figures can be implemented.

The communication unit 210 can communicate with an external device. Here, the external device may be the smart device 300 or the smart pot 100. The communication unit 210 may be wired or wirelessly connected to an external device, but may be implemented by wireless communication.

The information exchanged through the communication unit 210 may vary. The information exchanged with the smart flower pot 100 may be environmental information or touch information received from the smart pot 100 after being acquired from the sensor. The information exchanged with the smart device 300 may be information on a user's input received through the smart device 300. The information exchanged with the smart device 300 may be information for executing a specific application or function by controlling the smart device 300. [

The information exchanged through the communication unit 210 may be in various formats. For example, the information may be in the form of digital data encoded by a protocol that can be interpreted / processed by the server 200, the smart pot 100, and the smart device 300.

The memory 220 may store various types of information. The memory 220 may store various information such as environment information, touch information, and status information calculated based on environment information.

The memory 220 may store data temporarily or semi-permanently. Examples of the memory 220 include a hard disk drive (HDD), a solid state drive (SSD), a flash memory, a ROM (Read-Only Memory), a RAM This can be. The memory 220 may store an operating system (OS) for operating the server 200 or various data necessary or used for the operation of the server 200. Also, the memory 220 may store the multimedia contents received from the server 200.

The control unit 230 can perform calculation and processing of various kinds of information. For example, the control unit 230 may include an operation process for calculating state information from the environment information received from the smart flower pot 100, a calculation process for calculating a display attribute of the graphic object based on the state information and affinity information, and the like Can be performed.

The control unit 230 may be implemented as a computer or a similar device according to hardware, software, or a combination thereof so as to perform arithmetic operation and processing of various information. It may be a processor that stores and processes data in terms of hardware, and may be provided in a form of a program or a code that drives a circuit in software. For example, the control unit 230 can exchange data with the communication unit 210 and the memory 220. [ The control unit 230 may encode data to be transmitted to the smart device 300 according to a protocol shared with the smart device 300 and store the encoded data in the memory 220. The controller 230 calls the data stored in the memory 220 and decodes the data to interpret necessary information.

1.5. The configuration of the smart device 300

Hereinafter, the configuration of the smart device 300 will be described in detail.

5 is a block diagram illustrating a smart device 300 in connection with some embodiments of the invention.

5, the smart device 300 includes a communication unit 310, an input unit 320, an output unit 330, a memory 340, an interface unit 350, a control unit 360, and a power supply unit 370, And the like. The components shown in FIG. 5 list components that may typically be included in the smart device 300. Accordingly, it is needless to say that the smart device 300 including more or fewer components than those shown in the figures can be implemented.

The communication unit 310 may include one or more modules that enable communication between the smart device 300 and the communication system or with an external device. For example, the communication unit 310 may include an Internet module unit 311, a short-range communication module unit 312, and the like.

The Internet module unit 311 may refer to a module for Internet access. The Internet module 311 may be embedded in the smart device 300 or externally.

The short-range communication module 312 is a module for short-range communication. Bluetooth, radio frequency identification (RFID), infrared data association (IrDA), ultra wideband (UWB), ZigBee, etc. can be used as a short distance communication technology.

The input unit 320 may include a microphone 321, a touch sensor 322, and the like as a device for receiving a user input for controlling the smart device 300. [

The microphone 321 receives an external sound signal by a microphone in a communication mode, a recording mode, a voice recognition mode, or the like, and processes it as electrical voice data. The microphone 321 may be implemented with various noise reduction algorithms for eliminating noise generated in the process of receiving an external sound signal. In addition, various voice commands for driving the smart device 300 and executing functions through the microphone 321 can be input from the user. Hereinafter, the microphone 321 may be referred to as a voice input unit for convenience.

The touch sensor 322 may be configured to convert a change in a pressure applied to a specific portion of the display portion 331 or a capacitance generated in a specific portion of the display portion 331 into an electrical input signal. The touch sensor 322 can be configured to detect not only the position and area to be touched but also the pressure at the time of touch. If there is a touch input to the touch sensor 322, the corresponding signal is sent to the touch controller. The touch controller processes the signal and then transmits the corresponding data to the controller 360. The control unit 360 can know which area of the display unit 331 is touched or the like.

As described above, the touch sensor 322 may be connected to the display unit 331, but the touch sensor 322 may be provided in another form. For example, the touch sensor 322 may take the form of a touch film, a touch sheet, a touch pad, or the like.

The output unit 330 may include a display unit 331, an acoustic output unit 332, and the like.

The display unit 331 displays information processed in the smart device 300. [ For example, a UI (User Interface) or a GUI (Graphic User Interface) associated with the smart device 300 is displayed. The display unit 331 may be a liquid crystal display, a thin film transistor-liquid crystal display, an organic light-emitting diode, a flexible display, a three-dimensional display 3D display). The display unit 331 may be transparent or light transmissive. This can be referred to as a transparent display. A typical example of the transparent display is a transparent LCD or the like. The rear structure of the display portion 331 may also be of a light transmission type. With this structure, the user can see an object located behind the terminal body through the area occupied by the display portion 331 of the body.

There may be two or more display units 331 according to the implementation of the smart device 300. [ For example, in the smart device 300, the plurality of display portions 331 may be spaced apart from one another or may be disposed integrally with each other, or may be disposed on different surfaces.

In the case where the display portion 331 and the touch sensor 322 have a mutual layer structure, the display portion 331 can be used as an input device in addition to the output device.

The sound output unit 332 may output audio data received from the communication unit 310 or stored in the memory 340. [ The sound output unit 332 may output an acoustic signal related to a function performed in the smart device 300 (for example, a call signal reception tone, a message reception tone, and the like). The sound output unit 332 may include a receiver, a speaker, a buzzer, and the like.

The memory 340 may store a program for the operation of the controller 360 and temporarily store input / output data (e.g., messages, still images, moving pictures, etc.). The memory 340 may store data related to vibrations and sounds of various patterns that are output upon touch input on the touch screen.

The memory 340 may be a flash memory type, a hard disk type, a multimedia card micro type, a card type memory (for example, SD or XD memory), a RAM (Random Access Memory), SRAM (Static Random Access Memory), ROM (Read Only Memory), EEPROM (Electrically Erasable Programmable Read-Only Memory), PROM , An optical disc, and the like. The smart device 300 may operate in association with a web storage that performs storage functions of the memory on the Internet.

The interface unit 350 serves as a path for communication with all external devices connected to the smart device 300. The interface unit 350 receives data from an external device or receives power from the external device and transmits the data to each component in the smart device 300 or transmits data in the smart device 300 to an external device. For example, a wired / wireless headset port, an external charger port, a wired / wireless data port, a memory card port, a port for connecting a device having an identification module, an audio I / O port, A video I / O (Input / Output) port, an earphone port, and the like may be included in the interface unit 350.

In addition, the interface unit 350 may include a port connected to various input devices such as a mouse or a touch pad. The mouse is a device for receiving the position information of the pointer located on the display unit 331 and the click information of the user. A touch pad is a device that receives an input that a user touches using a part of a body, adjusts the position of the pointer in response to the input, and performs a click function at the position of the pointer.

The control unit 360 typically controls the overall operation of the smart device 300. For example, voice communication, data communication, video communication, and the like. The control unit 360 may include an image processing unit 361 for image processing.

The power supply unit 370 receives external power and internal power under the control of the controller 360 and supplies power necessary for operation of the respective components.

The various embodiments described herein may be embodied in a recording medium readable by a computer or similar device using, for example, software, hardware, or a combination thereof. According to a hardware implementation, the embodiments described herein may be implemented as application specific integrated circuits (ASICs), digital signal processors (DSPs), digital signal processing devices (DSPDs), programmable logic devices (PLDs), field programmable gate arrays May be implemented using at least one of processors, controllers, micro-controllers, microprocessors, and electrical units for performing functions. In some cases, And may be implemented by the control unit 360.

According to a software implementation, embodiments such as procedures or functions may be implemented with separate software modules that perform at least one function or operation. The software code may be implemented by a software application written in a suitable programming language. Further, the software codes may be stored in the memory 340 and executed by the control unit 360. [

Some or all of the operations of the smart device 300 described above can be realized by the smart device 300 driving the plant monitoring application. The input 320 of the smart device 300 may receive user input through a plant monitoring application. The output unit 330 of the smart device 300 may display information such as environmental information, status information, and affinity through graphical objects through a plant monitoring application. Plant monitoring applications are described in more detail below.

2. Plant Monitoring Applications

Hereinafter, an application driven by the smart device 300 according to an embodiment of the present invention will be described.

The application may be run on the smart device 300. The application may be executed using information received from the smart flower pot 100 and the server 200 interlocked with the smart device. Also, when the application is executed, the smart device 300 can notify the user of environmental information sensed by the smart pot 100, state information obtained from the environment information, and touch information sensed by the smart pot 100 .

6 shows an embodiment of a screen displayed in an application. Environmental information, status information, touch information, and the like can be displayed through the screen.

6 (a) shows an embodiment of an application screen in which temperature information is displayed.

Ambient temperature can be displayed at the top center of the screen. Ambient temperature can be 20 degrees Celsius. Below the display area of the ambient temperature, it can be displayed whether the current ambient temperature is within the optimum temperature range. When the ambient temperature is within the optimum temperature range, for example, referring to FIG. 6 (a), a 'normal' message may be displayed. In addition, the plant status information based on the temperature information may be displayed. Referring to FIG. 6 (a), the status information may be displayed in a text format as 'warm'.

6 (b) shows an embodiment of an application screen in which the level information is displayed.

At the top center of the screen, you can see how much of the water in the bucket is accommodated by the total bucket capacity. Referring to FIG. 6 (b), the water contained in the water tank may be 45% of the entire water tank capacity. Also, the application screen may represent the water level information as an image. Referring to FIG. 6 (b), the area where the water image at the bottom of the screen covers the screen may be enlarged according to the amount of water contained in the water bottle.

Below the display area of the received culture, it can be displayed whether the currently accepted culture is within the optimum range. If it is within the optimal range, a 'normal' message may be displayed with reference to FIG. 6 (b). In addition, the plant status information based on the water level information may be displayed. Referring to FIG. 6 (b), the status information may be displayed in a text format such as 'I am not thirsty, please give me water tomorrow'.

6 (c) shows an embodiment of an application screen in which a timeline reflecting touch information and a strobe record to be described later is displayed.

Touch information and a strobe record can be displayed in the form of a timeline. Referring to FIG. 6 (c), information on the date and time at which the user's touch was made may be displayed in the time line located on the left side of the screen. Information about what type of touch was made in the timeline can also be displayed. Referring to FIG. 6 (c), in the left area of the time line, information on what type of touch has been performed in accordance with the date displayed in the time line may be displayed.

The timeline may also display information about the water time. In the left area of the timeline, information about the water time can be displayed in conjunction with the timeline.

The timeline may also display environmental information or status information. The color from one end of the timeline to the other can be composed of various colors. The color of the timeline may reflect environmental information or status information. The color of the time line may be a color corresponding to the state information of the time at which the color is displayed. The color corresponding to the status information may match the color of the output unit 150 corresponding to the status information or the color of the aura object 20.

Timelines can also reflect plant growth. On the timeline, photos of plants can be displayed. The timeline can display the plant photographs at the time when the photographs of the plants are uploaded. The plant photographs can display not only photographs of plants but also comments of users on them.

7 is a diagram illustrating an embodiment of a character object 10 and an aura object 20 displayed on the screen of the smart device 300 when an application is running.

The character object 10 is a graphic object reflecting the degree of affection of the user to the plant. Affinity can be a measure of the user's interest in the plant and the behavior of the user taking care of the plant. The degree of affinity can be calculated based on the touch operation on the smart pot 100 of the user or on the voice of the user's plant. For example, if the user inputs a large amount of touch input to the smart pot 100, it can be determined that the affinity is high. The touch input of the user can be cumulatively recorded for the affinity calculation. Or affinity may be calculated according to the touch frequency. Therefore, when the touch input is performed a lot, the affinity increases, but when the touch input is decreased, the affinity can be lowered again.

The character object 10 may reflect the degree of affection. For example, the shape, shape, color, and movement of the graphic object may vary depending on the level of affinity. The shape of the character object 10 may change depending on the degree of affection. For example, if the degree of affinity exceeds a predetermined level, the character object 10 may have a different shape. The shape of the character object 10 can be permanently maintained in the changed shape. Or the shape of the character object 10 may be returned to its original form if the degree of affinity is lowered. The user can confirm the degree of affinity and how much the touch operation has been performed by checking the character object 10 .

The aura object 20 may reflect environmental information of the present time or status information of the plant. The aura object 20 can be distinguished from the character object 10 and displayed at a different position. Preferably, the aura object 20 may be displayed in the vicinity of the character object 10. In one example, the aura object 20 may be displayed in the background area behind the character object 10. The manner in which the aura object 20 displays information may vary. For example, the aura object 20 can display the state information of the plant by changing its shape or changing its color. If the plant state information changes, the color of the aura object 20 may be changed to a color corresponding to the changed state information.

With the above-described technical matter, the application can notify the user in a very intuitive way about the environmental information, the status information, the touch information, and the degree of affection for the user's plant.

The operation and function of the plant monitoring application within the plant monitoring system 1000 is described in more detail below. The operation of the smart device 300 may be largely accomplished through a plant monitoring application. It will be appreciated that in most cases it will be understood that the smart device 300 performs operations in the following, but it will be understood that substantially such operations are performed in the smart device 300 through the plant monitoring application.

3. Operation and function of the plant monitoring system (1000)

Hereinafter, embodiments of various operations and functions performed by the above-described various configurations in the plant monitoring system 1000 according to an embodiment of the present invention will be described.

3.1. Smart pots (100) - Smart devices (300) Bindings

As described above, in the plant monitoring system 1000 disclosed by the present invention, there may be a plurality of smart pots 100 and smart devices 300 linked to the server 200.

8 is a flowchart illustrating a method for the server 200 to communicate with each smart pot 100 and each smart device 300 using the IDs assigned to the plurality of smart pots 100 and the plurality of smart devices 300 It is a flowchart.

Referring to FIG. 8, the server 200 may acquire IDs assigned to the smart pots 100 and the smart devices 300 (S1010). The server 200 may obtain a binding table in which the smart pot number 100 and the identity of the smart device 300 used by the user possessing the smart pot 100 are recorded. After that, the server 200 may transmit the ID of the device that transmits the information together with the smart pot 100 or the device including the smart device 300 (S1030). The server 200 can obtain the ID of another device bound to the ID of the device that transmitted the information with reference to the binding table (S 1040). Thereafter, the server 200 may transmit information to the device having the ID of the other device (S1050).

Each step will be described in detail below.

The server 200 may obtain the IDs assigned to the smart pots 100 and the smart devices 300 (S1010).

Each smart pot 100 and each smart device 300 can have a unique ID. The server 200 can identify each SmartPower 100 and each smart device 300 through a unique ID.

The identity of the smart device 300 may be assigned to the smart device 300, for example, by an application running on the smart device 300. Alternatively, a unique ID may be assigned to the application itself operated by the smart device 300.

The ID of the smart pot 100 may be given to the controller 140 included in the smart pot 100 or may be given to the smart pot 100 by the controller 140. [

Or a unique ID may be given to each smart pot 100 and each smart device 300 by the server 200. [

The server 200 may obtain a binding table in which the smart pot number 100 and the identity of the smart device 300 used by the user who owns the smart pot 100 are recorded.

The IDs of the smart pots 100 and the IDs of the smart devices 300 in which the application that reflects the states of the smart pots 100 may be bound to each other. The binding relationship may be managed by a binding table stored in the server 200. [

The binding relationship can be established through a process of inputting a unique ID of the smart pot 100 used by the user through the application, for example. The server 200 establishes a binding relationship between the ID of the smart device 300 and the ID of the input smart pot 100, and records the binding relationship in a table 220 .

The server 200 may transmit the ID of the device that transmits the information together with the device including the smart flower pot 100 or the smart device 300 (S1030). The server 200 can obtain the ID of another device bound to the ID of the device that transmitted the information with reference to the binding table (S 1040). Thereafter, the server 200 may transmit information to the device having the ID of the other device (S1050).

The server 200 can receive the ID of the smart flower pot 100 together with the environmental information and the touch information from the smart pot flower pot 100. [ The server 200 can obtain the ID of the smart device 300 bound to the ID of the smart flower pot 100 by referring to the binding table. The server 200 may transmit the processed information of the environmental information and the touch information to the smart device 300 having the ID obtained as the binding.

Similarly, when the server 200 receives information such as a user input from the smart device 300 in the reverse path opposite to the above-described path, the ID of an application running on the smart device 300 or the smart device 300 The server 200 acquires the ID of the smart pot 100 that the server 200 is bound to the smart device 300 or the ID of the application and the server 200 acquires A process of transmitting necessary information to the smart flower pot 100 having the ID can be performed.

At least one smart flower pot 100 and at least one smart device 300 running the application may exchange information through the server 200 through the above process.

The description of the exchange of information between the SmartPower 100 and the smart device 300 is made through the process described above and the description of the identity and binding relationship between the SmartPower 100 and the smart device 300 is omitted However, it should be understood that information exchange is performed through the above-described process.

3.2. Operation of Plant Monitoring System 1000 Using Environmental Information

Hereinafter, the operation using the environmental information of the embodiment of the plant monitoring system 1000 according to an embodiment of the present invention will be described.

3.2.1. Environmental Information

The SmartPower 100 may include at least one environmental information sensor 130 for sensing environmental information as described above. The environmental information to be sensed may be temperature information, humidity information, brightness information, or water level information. The environment information sensor 130 may sense environment information in real time or may periodically sense environment information according to a predetermined time interval. Or the environment information sensor 130 may sense environmental information when a user's input is received from the smart device 300. [

The environmental information sensed through the environmental information sensor 130 may be transmitted to the control unit 140.

3.2.2. Status information

The status information may be information reflecting the status of the plant, such as what the plant is in, what the plant needs, and how severe the plant needs to be. The status information can be judged based on the environment information.

Let's look at the computation process for obtaining state information. The status information can be obtained based on the environment information. A predetermined criterion may correspond to each environmental information. The predetermined criteria corresponding to one environmental information may be one or a plurality of predetermined criteria.

For example, the status information may be determined based on whether or not the environment information satisfies a predetermined criterion. For example, if the environment information satisfies a predetermined criterion, the status information may indicate a 'satisfactory state'. In another example, if the environment information is unsatisfied with a predetermined criterion, the status information may indicate an 'unsatisfactory status'. The satisfaction state does not mean that the environment information is within the optimum range, and the unsatisfied state does not mean that the environment information is out of the optimum range. For example, a predetermined criterion may be set as a negative criterion. Specifically, when the predetermined criterion is " the water level is less than the minimum value ", the fact that the water level information satisfies the predetermined criterion may mean that the water level information is outside the optimum range. Conversely, when the predetermined criterion is " the water level is below the minimum value, or below the maximum value ", it can be said that the water level information satisfies the predetermined criterion.

The status information may be determined by further considering the type of environmental information that is satisfied or unsatisfactory. In other words, when there is environmental information which is unsatisfactory among the environmental information, the status information can reflect the kind of environmental information that is dissatisfied. For example, when the temperature information is unsatisfied with a predetermined condition corresponding to the temperature information in the environment information, the state information may indicate 'temperature unsatisfactory'. In another example, when the illumination information in the environmental information is unsatisfactory, the state information may indicate 'illuminance dissatisfaction'.

The status information can be determined by further considering the type of environment information that is satisfied. For example, when the temperature information in the environmental information satisfies a predetermined criterion, the state information may indicate 'temperature satisfaction'.

The predetermined criterion may be to ask whether or not the environment information belongs to a predetermined section. The predetermined interval may include a minimum value and a maximum value, and may include only a minimum value or a maximum value. The status information can be obtained by comparing the environment information with a minimum value or a maximum value. For example, if the temperature information in the environment information exceeds a predetermined satisfaction temperature range, the status information may indicate 'over temperature'. In another example, when the temperature information of the environment information is less than a predetermined satisfactory temperature range, the status information may indicate 'under temperature'.

The status information may be determined by further considering the number of satisfied or unsatisfactory environment information. For example, the status information may be determined to reflect the number of unsatisfied environmental information in the environment information. For example, when two or more pieces of environmental information in the environment information are unsatisfied, the status information may be determined as a 'bad condition'. As another example, when all of the environmental information satisfies a predetermined criterion, the status information can be determined as a 'good condition'.

On the other hand, the state information can be determined by considering all the various factors described above.

As another example of the status information, the status information may include a type and a level. Various elements of the computation process that may be used to obtain the above-described state information may be used to obtain the type and level.

The type may be information about the lack of environmental information or the excess in the environment provided to the plant. The type can be obtained based on the kind of environment information satisfying or unsatisfying the predetermined condition and the predetermined condition. For example, if the water level information is below a predetermined water level, the type may first be determined to be associated with water level information. Since the level information does not satisfy the predetermined level section, the type can be obtained as a water shortage state. In another example, if the temperature information is greater than or equal to a predetermined maximum value, the type can be determined to be related to the temperature information, and the temperature can be hot because the temperature information is higher than a predetermined condition. If the temperature information is less than the predetermined minimum value, the type is determined to be temperature information, and the temperature information is not more than the minimum value, so that the type can be in a cold state

Levels can be information about the extent to which environmental information is lacking or excessive in the environment provided to the plant. Levels can be obtained in a variety of ways.

For example, the level can be determined according to the 'number' of environmental information that satisfies a predetermined criterion. For example, when a predetermined reference corresponding to the temperature information is required to be within the optimum temperature range and a predetermined reference corresponding to the water level information requests the water level to be within the optimum range, both the temperature information and the water level information And may be unsatisfied with a predetermined condition. In this case, the level can be obtained as a 'bad state'. As another example, in the above-mentioned examples of the temperature information and the water level information, there may be a case where the predetermined reference corresponding to the brightness information is within the optimum range, and the brightness information is unsatisfied with the predetermined reference. In this case, since there are three pieces of environment information that are unsatisfied with the predetermined criteria, the level can be obtained as a 'very bad condition'.

Or the level may be determined on the basis of how far environmental information deviates from a predetermined condition. The level can be determined based on the 'difference' between environmental information and predetermined conditions. For example, if the temperature information is greater than or equal to the maximum value but close to the maximum value, the level may be obtained as " hot. &Quot; If the temperature information is greater than the maximum value and significantly different from the maximum value, the level can be obtained as 'very hot'.

The state information may include a type and a level at the same time, or may include only one of them. This will be described later in detail with reference to FIG.

FIG. 9 shows an embodiment of the operation of the output unit 150 according to the status information that can be obtained based on the environment information. 9 is merely an example of state information, and the criteria for obtaining state information based on the environmental information, the state information to be obtained and the operation of the output unit 150 accordingly are not shown in the various methods Lt; / RTI >

As an example in which the state information is obtained, a case where temperature information is used among environmental information is described. If the ambient temperature value included in the sensed temperature information is equal to or greater than the maximum value of the optimum temperature range of the plant, the controller 140 may determine that the plant is in a hot state and obtain a 'hot state' as state information. Here, the hot state may be one of the types of state information. Accordingly, the smart pot 100 may inform the user that the plant is in a hot state through the output unit 150, thereby inducing an effort from the user to lower the plant ambient temperature.

For example, if the amount of light of the wavelength required for photosynthesis included in the sensed luminous intensity information is less than the minimum value, the controller 140 determines that the plant is in the 'light-deficient state' Can be obtained. Here, the light short condition may be one of the types of status information. The control unit 140 can notify the user of the low light state through the output unit 150. [

In another example, if the level of the culture liquid contained in the sensed level information is lower than the minimum value required by the plant, the control unit 140 determines that the plant is in the 'water shortage state' Can be obtained. The water shortage state may be one of the types of state information. The smart pot 100 can inform the user of the water shortage status of the plant through the output unit 150.

The above-described state information is an example of a type determined according to 'type' of environmental information outside the optimal range.

On the contrary, the state information described later is an example of a level, which is information on the seriousness of the state. The control unit 140 may use two or more pieces of environmental information to acquire a level. For example, when it is determined that all of the environmental information sensed by the control unit 140 is located within the optimum range set in each environmental information, the control unit 140 determines that the optimal growth environment is provided to the plant, Good state 'can be obtained. Here, a good state may be an example of a bar level determined by the number of environment information satisfying the optimum range, which is a predetermined criterion.

In another example, when the controller 140 determines that two environmental information out of the environmental information sensed by the controller 140 is out of the optimal range, the controller 140 can acquire a 'bad state' as state information of the plant. If three or more environment information out of the environment information sensed by the controller 140 is out of the optimum range, the controller 140 can acquire a 'serious state' as status information. The smart pot 100 can notify the degree of the state of the plant by notifying the bad state and the serious state through the output unit 150.

Fig. 10 specifically explains an embodiment of a method in which state information is acquired based on temperature information among environmental information.

Referring to Fig. 10 (a), a predetermined criterion may require that temperature information be included in the optimum interval including the minimum value _Tmin and the maximum value _Tmax . Referring to FIG. 10 (b), the environment information and the corresponding status information and the operation of the output unit 150 can be known.

The first temperature information T1 is less than the minimum value Tmin. Accordingly, the state information can be obtained in a cold state, and the output unit 150 can emit blue light.

The second temperature information T2 is less than the minimum value Tmin and the maximum value Tmax. Thus, the state information can be in a warm state. The state information can be obtained in a good state, and the output unit 150 can emit green light.

The third temperature information is not less than the maximum value Tmax and is a value near the maximum value Tmax. Thus, the state information can be obtained in a hot state. The output unit 150 may emit red light.

The fourth temperature information is greater than or equal to the maximum value Tmax, and has a large difference from the maximum value Tmax. Accordingly, the state information can be obtained in a very hot state. The output unit 150 can emit flashing red light.

When the third temperature information T3 is obtained as the temperature information and the predetermined reference is unsatisfactory and the water level information W1 is acquired below the predetermined minimum value, there are two pieces of environment information unsatisfied with the predetermined criteria , The state information can be obtained in a bad state. Accordingly, the output unit 150 can display gray light.

Here, the cold state, the warm state, and the hot state reflect whether or not the temperature information of the plant cultivation environment satisfies a predetermined criterion, and thus may reflect 'type only' in the state information. On the other hand, a very hot state reflects a serious deviation of the temperature range from the optimal range, so it may reflect 'not only type but also level' in the status information. In addition, the bad condition reflects the seriousness because the temperature information and the water level information are out of the optimum range, and thus may reflect 'level only' among the status information.

3.2.3. Acquisition of criteria for status information according to plant species

The optimal environment for plant growth depends on the type of plant. For example, succulent plants, such as cacti, may require a relatively small amount of water compared to other plant species, and plant species classified as tropical plants may have a maximum of the optimum temperature range compared to other plant species. The plant monitoring system 1000 according to an embodiment of the present invention can provide a plant with an optimized cultivation environment in consideration of the inherent characteristics of the plant.

The smart flower pot 100 can acquire status information determination criteria to acquire status information based on environment information. The status information determination criterion is information that serves as a criterion for determining status information from environment information. The status information determination criterion may be information set to fit the plant species.

For example, the status information determination criterion may be a minimum temperature value and a maximum temperature value constituting the optimum temperature range with respect to the temperature information in the environment information. The state information determination criterion may be the highest water level and the lowest water level constituting the optimum water level of the culture liquid with respect to the water level information. The status information determination criterion may be information on the wavelength of light and amount of light required by the plant for the luminance information.

The time at which the status information determination criteria are obtained may be after the environmental information sensing, but preferably the status information determination criteria can be obtained prior to environmental information sensing.

11 is a diagram of an embodiment of a method by which a status information determination criterion is obtained. According to FIG. 11, a status information determination reference database may be obtained first (S2010). Plant species information planted in the smart pot 100 may then be obtained (S2020). Thereafter, a status information determination criterion corresponding to the plant species may be obtained from the status information determination criteria database (S2030)

Each step will be described in detail below.

The state information judgment reference database can be obtained (S2010).

The database in which the status information determination criteria are recorded may be stored in the memory 220 of the server 200. The smart device 300 may receive all or part of the database of status information determination criteria from the server 200. [ Or a database of status information determination criteria may be stored in the memory 340 of the smart device 300. [

The status information determination criteria database may be updated. The status information determination criterion for the new plant species may be added by the administrator or the criterion for determining the status information for the existing input plant species may be changed.

Plant species information planted in the smart pot 100 may then be obtained (S2020).

Methods for obtaining plant species information can vary.

For example, the smart device 300 may obtain information about the plant species planted in the smart pot 100 from a user by a driving application. The smart device 300 may transmit the information about the plant species to the server 200. [

In another example, the smart device 300 may receive a photograph of a plant planted in the smart pot 100 from a user. The smart device 300 may transmit a photograph of the plant to the server 200. The server 200 can determine the type of the plant based on the photograph of the plant.

Thereafter, a status information determination criterion corresponding to the plant species may be obtained from the status information determination criteria database (S2030)

The server 200 or the controllers 140 and 230 of the smart pot 100 may obtain a criterion corresponding to the plant species information obtained from the status information determination criteria database.

3.2.4. Obtain Status Information

The control unit 140 can receive environment information from the environment information sensor 130. [ The control unit 140 can acquire the state information of the plant based on the received environment information.

The way plant status information is obtained may vary.

12 is a diagram of an example of how smart pot 100, server 200, or smart device 300 obtain state information from environmental information.

First, a state information determination criterion according to plant species can be obtained (S2110). Thereafter, the smart flower pot 100, the server 200, or the smart appliance 300 may acquire environment information (S2120). Thereafter, the smart flower pot 100, the server 200, or the smart appliance 300 may obtain status information using the status information determination criteria based on the environment information (S2130). The smart flower pot 100, the server 200 or the smart appliance 300 may then display status information (S2140)

Each step will be described in detail below.

First, a status information determination criterion can be obtained (S2110). This step is for obtaining the state information judgment criterion corresponding to the plant species from the state information judgment reference database, The status information determination criterion items and the description in FIGS. 9 and 10 have been described.

The smart flower pot 100, the server 200, or the smart appliance 300 may acquire environment information (S2120). The step of acquiring environmental information is the same as the above-described step 3.2.1. Can be performed by the steps described in the environmental information item.

Thereafter, the SmartPower 100, the server 200, or the smart device 300 may acquire status information using the status information determination criteria based on the environment information (S2130).

The calculation process of calculating the state information from the environment information may be performed by the control unit 140 of the smart pollen 100 or by the control unit 210 of the server 200 or the control unit 310 of the smart device 300 . Described below or in more detail is the description of the operation of the smart pot 100 or the server 200 that it is possible to describe the status information in the smart pot 100 for convenience or that the server 200 can calculate the status information can do. However, this description does not mean that the status information calculation process is performed only in the configuration of either the SmartPart 100 or the server 200, and it should be interpreted that the status information is calculated. It will be appreciated that even if the state information calculation process is described using the smart flower pot 100 as a main body, the server 200 can perform the same process as a subject. Conversely, even if the state information calculation process is described using the server 200 as a subject, it can be appreciated that the SmartPot 100 can perform the same process as a subject.

When acquiring status information, the above-described status information determination criteria can be used. Other status information criteria may be applied depending on plant species. Therefore, different status information can be obtained from the same environmental information depending on the plant species.

Then, the SmartPower 100, the server 200, or the smart device 300 may display status information (S2140).

The smart pot 100 may display status information through the output unit 150. For this, see 3.4.1.1 below. The state information display item will be described in detail.

The server 200 can acquire the aura display attribute based on the acquired state information. The server 200 may transmit the aura display attribute to the smart device 300. The smart device 300 may inform the user of the status information by displaying the aura display attribute. See 3.4.2.1 below. The display properties of the aura of the item will be described in detail.

3.3. Recognition of gestures

Hereinafter, an operation in which the plant monitoring system 1000 acquires a gesture according to a touch input will be described.

Here, the gesture refers to various operations in which the user touches the plant or the smart pot 100. The gesture may be determined based on the touch input received by the touch sensor 120. [ In other words, the gesture can be judged based on information such as the type, order, position, time, and area of the touch input.

The gestures that the smart pot 100 can distinguish and recognize can be of various kinds. For example, a gesture can include a stroked gesture, a smart gesture, and a wrapping gesture. Of course, more types of gestures can be recognized based on various information of the touch input.

Depending on the type of gesture recognized, the system can perform various actions. The actions performed according to the type of gesture may be different or may be different for each gesture type.

For example, if a stroked gesture is recognized, the system 1000 may generate a stroked record. The system 1000 can improve the affinity based on this.

As another example, if a smart gesture is detected, the system 1000 may display a push message to the user that executes the application. The smart device 300 may receive a stroking record from the server 200. [

An example of the above-described operation is only one of various embodiments that can correspond to a gesture, and does not limit the operation.

3.3.1 Behavior of Plant Monitoring System (1000) on Stutter

The following describes the operation of the plant monitoring system 1000 for a stroking gesture.

3.3.1. Detecting stroking gestures

The smart pot 100 according to the present invention may include a touch sensor 120. The touch sensor 120 may be provided in various forms. The touch sensor 120 may include a first touch sensor 121 installed along the circumferential direction of the pollen case 110 at an upper portion of the pollen case 110 and a second touch sensor 121 disposed below the pollen case 110 And a second touch sensor 122 spaced apart from the first touch sensor 121 by a predetermined distance in the up and down direction. Hereinafter, in the smart pot 100 having the first touch sensor 121 and the second touch sensor 122, a first touch sensor 121 and a second touch sensor 122 are used to detect a user's stroking gesture Describe the detection.

Hereinafter, a touch input by the first touch sensor 121 is referred to as a first touch input, and a touch input by the second touch sensor 122 is referred to as a second touch input.

FIG. 13 is a view for explaining that a stroking gesture is sensed by the first touch sensor 121 and the second touch sensor 122. FIG.

Referring to FIG. 13, when the user strokes the pots from top to bottom, the smart pot 100 receives the first touch input and then receives the second touch input. The SmartPower 100 may sense that the stroking gesture has been performed when the second touch input is received at the second touch point within a predetermined time after receiving the first touch input at the first touch point.

Here, the 'touch point' may refer to the time when the touch input starts to be received. Accordingly, even if the second touch input is started to be received while the first touch input is continued, the smart pot 100 can sense the stroking gesture. In addition, even if the first touch input is first started, the second touch input is received, and the second touch input is stopped before the first touch input, the SmartPower 100 can sense the stroking gesture.

The smart flower pot 100 can perform a predetermined operation when it detects a stroking gesture. The predetermined operation may vary. The predetermined action may be to display through the output 150 of the smart pollen 100 that the smart pollen 100 senses the stroking gesture. Or the predetermined action may be to send a message to the server 200 requesting that the smart pot 100 generate a stroking record.

3.3.3. Create a stroking record

14 is a diagram for explaining generation of a strobe record including information on a stroking gesture.

The smart flower pot 100, the server 200, or the smart device 300 may generate a strobe record that includes information about the stroking gesture when it is sensed. The stroking record may include information such as the date and time at which the stroking gesture was sensed, affection and growth characteristics, and the like.

Referring to FIG. 14, an embodiment of a stroked gesture can be seen. In the table of FIG. 14, the first column and the second column show information on the date and time when the stroking gesture was detected.

The third column of the table displays information about the degree of affection obtained from the stroking gesture. A lot of stroking gestures can mean that the user has a great affection for the plant. It has been described that affinity can be obtained from a stroked gesture in various ways. This table is based on the cumulative number of times the affinity is detected for the stroking gesture.

Affinity may have an upper limit that is reset or no longer increases under certain circumstances. For example, affinity may be reset by the user's input if the plant planted in smart pot 100 is replaced with another plant.

Also, an upper limit value of the increase amount that can be obtained within a predetermined time interval can be set for the affinity. Affinity can be kept from continually increasing information about continuing to do stroking gestures to artificially increase affection.

The fourth column of the table displays information about growth properties. The growth attribute is one of the display attributes of the character object 10 and is information indicating the size of the character object 10. [ The growth characteristics can be calculated according to the degree of affection. For example, when the affinity is equal to or greater than a predetermined value, the growth property may increase. As the growth property increases, the size of the character object 10 may increase. For example, referring to FIG. 14, the predetermined values for affinity information may be set to 5 and 10. When the affinity is 5, the growth property can be increased from A to B, which is a value larger than A, and when the affinity information is 10, the growth property can be increased from B to C,

The strobe record may be stored in a memory (not shown) of the smart pot 100 itself or may be stored in the memory 220 of the server 200 or the memory 340 of the smart device 300.

3.3.2. The operation of the plant monitoring system 1000 relating to smart

The following describes the operation of the plant monitoring system 1000 with respect to smart gestures.

3.4.1. Smart Detection

The smart pot 100 according to the present invention can sense smart gestures. The smart gesture refers to an operation of touching one area of the touch sensor 120 twice or more continuously in a short time.

FIG. 15 is a diagram for explaining how to detect a smart gesture in the smart pot 100. FIG. Referring to FIG. 15, the smart pot 100 may detect that a smart gesture has been performed when a touch is received twice or more within a predetermined time period through the touch sensor 120. FIG.

At this time, the two touches may be received by the same touch sensor 120. Alternatively, the two touches may be received by different touch sensors 120. FIG.

The predetermined time for acquiring a smart gesture may be different from a predetermined time for acquiring a stroked gesture.

In addition, the touch sensor 120 for recognizing the smart gesture may be different from the touch sensor 120 for recognizing the smear gesture. That is, the touch sensor 120 for a smart gesture may be a touch sensor 120 that is sensitive to vibration or pressure, while the touch sensor 120 for a stroked gesture may be a touch sensor 120 that is sensitive to a touch area. For example, the touch sensor 120 for a smart gesture may be a vibration sensitive piezoelectric sensor.

3.4. The output operation of the system 1000

Hereinafter, the output operation of the plant monitoring system 1000 according to an embodiment of the present invention will be described.

3.4.1. Output operation of smart pot 100

Hereinafter, the output operation of the smart pot 100 will be described.

The output operation of the output unit 150 may be performed in various ways.

For example, the output unit 150 may display various information by color of light, blink of light, intensity of light, or the like. Or output unit 150 may display information in a manner such as text, still image, or moving image. Or the output unit can display information by outputting a voice message corresponding to various information.

Hereinafter, the operation of the output unit 150 for displaying status information, the operation of the output unit 150 according to the stroking gesture, and the operation of the output unit 150 according to the smart gesture Describe the operation.

3.4.1.1. Display status information of smart pot (100)

The SmartPower 100 can notify the user of the acquired status information through the output unit 150. [ The display method of the status information and the operation of the output unit 150 may be various. As a display method, referring to the tables of FIGS. 9 and 10, the light emitting device of the output unit 150 may emit light of a color corresponding to each status information.

Referring to FIG. 9, the output unit 150 may display red light corresponding to a hot state. The output unit 150 can display the blue light corresponding to the cold state. The output unit 150 can display the yellow light corresponding to the water shortage state. The output unit 150 can display the purple light in response to the light shortage state. The output unit 150 can display green light corresponding to a good state. The output unit 150 can display gray light corresponding to a bad state.

Referring to FIG. 10, the output unit 150 may display blue light corresponding to a cold state. The output unit 150 can display green light corresponding to a warm state. The output unit 150 can display the red light corresponding to the hot state. The output unit 150 can display the flashing red light corresponding to a very hot state. The output unit 150 can display gray light corresponding to a bad state.

As described above, the output unit 150 may reflect the type and / or the level among the status information.

Since the above-described display methods are only examples of various display methods, various embodiments of the display method of the present invention are not limited.

16 is a view showing the appearance of the smart pot 100 when a display operation is performed by the output unit 150 in the smart pot 100 in accordance with an embodiment of the present invention.

In FIG. 16 (a), green light may be displayed on the output unit 150. The smart pot 100 can indicate that the plant is in a good state by displaying green light.

In Fig. 16 (b), red light may be displayed on the output unit 150. Fig. The SmartPower 100 may change the light emission color of the output unit 150 from the existing green to the red according to the change of the status information. Through the above process, the user can be notified that the status information of the plant has been changed, and can inform the user that the user will check the cultivation environment provided to the flowerpot.

3.4.1.2. Show stroking gesture

17 is a diagram illustrating an embodiment of the operation of the output 150 of the smart pot 100 when a stroking gesture is sensed.

Referring to FIG. 17, the smart pot 100 may detect a stroking gesture. The smart pot 100 may then indicate through the output 150 that it has sensed the stroking gesture. For example, the output unit 150 can display different luminescent colors at predetermined time intervals. The output unit 150 may repeat the on and off operations of the light emitting unit to display the flashing light when the light emitting color is displayed.

The display operation of Fig. 17 is merely an example, and it is also possible to inform the user of the detection of the stroking gesture in various ways. For example, the output may notify detection of a stroking gesture with a voice message.

3.4.1.3. Clever gesture display

18 is a diagram illustrating one embodiment of the operation of the output 150 of the smart pot 100 when a smart gesture is detected. If smart pot 100 senses a smart gesture, smart pot 100 may indicate through smart output 100 that smart smart pot 100 has detected a smart smart gesture. For example, the output unit 150 can indicate that the smart gesture is detected by repeating turning on and off the light emitting unit.

The display operation of Fig. 18 is merely an example, and it is also possible to notify the user that a smart gesture is detected in various ways. For example, the output can announce the detection of a smart gesture with a voice message.

3.4.2. The output operation of the smart device 300

Hereinafter, an operation of displaying smart potted plants 100 or plant-related information in the smart device 300 will be described. The information displayed on the smart device 300 may vary. For example, environmental information, status information, touch information, a strobe record, and the like may be displayed. How to display can also vary. For example, the smart device 300 may display the information using graphical objects. The graphics object may be plural. The display attributes may be determined according to the information to be reflected by the graphic objects.

For example, the graphic object may include an aura object 20 and a character object 10. The aura object 20 and the character object 10 can be expressed by reflecting different information, respectively. Or the aura object 20 and the character object 10 may reflect the same information in a different manner. For example, the aura object 20 and the character object 10 may reflect the status information. At this time, the aura object 20 can reflect the state information while changing its color, and the character object 10 can reflect the state information while changing its shape. Alternatively, the aura object 20 and the character object 10 may reflect the degree of affection. The aura object 20 can reflect the degree of affection while changing its color, and the character object 10 can reflect the affection while changing its shape.

Hereinafter, as a method of displaying the smart object 300, a method of displaying the graphic object 10 reflecting the manner and the degree of affection of the smart object 300 by reflecting the state information and displaying the aura object 20 Will be described.

The smart device 300 may receive all or a portion of the information from the smart flower pot 100 or the server 200. The smart device 300 may process the received partial information in the control unit 360 to acquire new information. For example, after receiving the environment information, the smart device 300 can acquire the status information based on the environment information. Or the smart device 300 may receive status information directly from the smart flower pot 100 or the server 200. [ Hereinafter, it is assumed that the subject of the calculation process for acquiring information is the server 200 for the sake of convenience. However, it will be appreciated that the above calculation procedures can be performed in the smart pot 100 or the smart device 300. [

3.4.2.1. Display of status information through the aura object 20

Hereinafter, with reference to FIG. 19, description will be given of how the status information is displayed by the aura object 20 as an embodiment of the method of displaying the status information in the smart device 300. FIG.

Referring to FIG. 19, a display attribute of the aura object 20 may be obtained based on state information (S3010). Then, the display attribute of the aura object 20 may be displayed (S3020).

Each step will be described in detail below.

First, the display attribute of the aura object 20 can be obtained based on the state information (S3010).

The display attributes of the aura object 20 refer to the shape, shape, color, motion, and combinations of the aura objects 20 for displaying status information in the smart device 300 bound to the smart flower pot 100. [ The aura object 20 may reflect the state information using at least one of the display attributes.

The manner in which the display attribute of the aura object 20 reflects the state information may vary. For example, the status information may be reflected according to the color of the display attribute of the aura object 20. More specifically, the type of status information may be reflected depending on the color. More specifically, the type and / or level of status information may be reflected depending on the color. For example, a color reflecting the type may be associated with each type of status information. In addition, when the degree of each state information becomes serious, that is, when the level is changed, the brightness of color, saturation, and shade change, and the degree of state information can be reflected.

For example, the state information may be reflected according to the shape of the display attribute of the aura object 20. More specifically, the type of state information may be reflected depending on the shape. More specifically, the type and / or level of status information may be reflected depending on the shape. For example, when the degree of the state information is moderate, the aura object 20 can maintain a spherical shape. When the degree of the state information becomes severe at a later stage, the aura object 20 may be changed into a sharp spiky spherical shape.

Various state information can be reflected in various ways by the shape or movement of the aura object 20 even with the above-mentioned exception.

The display attributes of the various aura objects 20 may be stored in the memories 220 and 320 of the server 200 or the smart device 300 in correspondence with respective status information. The server 200 or the smart device 300 can obtain the display attribute of the aura object 20 by calling the display attribute of the aura object 20 corresponding to the acquired status information from the memory 220. [ The server 200 may transmit the display attribute of the aura object 20 to the smart device 300 when the display attribute of the aura object 20 is obtained from the server 200. [

Then, the display attribute of the aura object 20 may be displayed (S3020).

The smart device 300 can inform the user of the status information of the plant by displaying the display attribute of the aura object 20. [

In Fig. 20, an embodiment of the display attribute of the aura object 20 corresponding to the state information is displayed.

20 (a) shows that the display attribute of the aura object 20 is acquired in green when the state information is in a good state.

FIG. 20 (b) shows that the display attribute of the aura object 20 is obtained in purple when the state information is in a light-deficient state.

Fig. 20 (c) shows that the display attribute of the aura object 20 is acquired in blue when the state information is in a state of excessive water.

Fig. 20 (d) shows that the display attribute of the aura object 20 is obtained in orange when the state information is in a water shortage state.

FIG. 20 (e) shows that the display attribute of the aura object 20 is acquired in gray when the state information is in a bad state.

The display attribute of FIG. 20 described above is merely an embodiment, and the smart device 300 can display status information in various display attributes of the aura object 20 and a combination thereof.

3.4.2.2. Display of the rhythm record through the character object (10)

Hereinafter, it will be described with reference to FIG. 21 that a character object 10 reflecting the above-described strobe recording is displayed in the smart device 300. FIG.

Referring to FIG. 21, the display attribute of the character object 10 may be obtained based on the stroked record (S3110). Then, the display attribute of the character object 10 may be displayed (S3120). Each step will be described in detail below.

First, the display attribute of the character object 10 may be obtained based on the stroking record (S3110).

The display attribute of the character object 10 refers to the shape, shape, color, movement, and combinations of the character objects 10. The display attribute of the character object 10 may be determined by reflecting touch information, affection or stroking record.

The character object 10 may include various display attributes for expressing affinity. For example, the character object 10 can express affinity through its shape. Specifically, the shape of the character object 10 initially starts from a simple sphere shape, but if the degree of affinity increases, the shape of the character object 10 may be formed or the shape of the limb may be changed.

As another example, the display attribute of the character object 10 may include the growth attributes described above. A large growth attribute can mean that there is a great deal of affection. Growth properties can be calculated based on affinity information.

The display attributes of the character object 10 may be obtained in the smartpot 100 or in the server 200 and thereafter transmitted to the smart device 300. [

Then, the display attribute of the character object 10 may be displayed (S3120)

The smart device 300 may receive the display attribute of the character object 10 from the server 200. [ The smart device 300 can display the display attribute of the character object 10 to inform the user of the degree of affection for the plant based on the touch information.

22 is a diagram relating to an embodiment in which the character object 10 is displayed. The character object 10 shown in Fig. 22 (a) is initially a small sphere. As the degree of affinity increases, the size of the character object 10 displayed in FIG. 22 (b) may increase. At the same time, the shape of the character object 10 can be changed so that a part of the spherical body protrudes in the form of a tail. Thereafter, as the degree of affinity further increases, the character object 10 displayed in FIG. 22 (c) can be further increased in size. At the same time, the shape of the character object 10 may change from a spherical body to a shape protruding like a horn.

Through the above-described process, the smart device 300 can display the graphical object reflecting the status information and the degree of affinity, thereby informing the user of the status information and the degree of affection.

3.5. The push operation of the system 1000

Hereinafter, an operation of displaying a push message to a user in the plant monitoring system 1000 according to an embodiment of the present invention will be described.

3.5.1. Push message

The plant monitoring system 1000 can inform the user when information is acquired or information is changed. The method of informing the user may be a method of displaying a push message in the smart device 300. [

The information may be various information that the user needs to know about the change. For example, the information may be status information. Or the information may be a display attribute of the aura object 20. Or the information may be a display attribute of the character object 10. Or the information may be touch information itself or information related to touch information.

A push message may be strictly speaking a message transfer between different components informing acquisition or modification of information in one direction. The transmission of a push message, as used herein, may refer to the transmission of a message informing the acquisition and modification of information between components of the system, such as the smart flower pot 100, the server 200 and the smart device 300. Alternatively, the transmission of the push message referred to herein may include outputting a message informing the user of acquisition and change of information through the screen of the smart device 300, within an acceptable range.

23 is a diagram of a flowchart of a method in which a push message is displayed to a user as a predetermined condition is satisfied.

First, a predetermined condition can be satisfied (S4010). Thereafter, a push message indicating satisfaction of a predetermined condition may be output to the user (S4020). Thereafter, an input for selecting a push message from the user may be received (S4030). Lastly, information related to a predetermined condition may be displayed (S4040).

In the following, each step will be described in detail.

First, a predetermined condition can be satisfied (S4010).

The predetermined condition may be related to information associated with smart pot 100 or plant. The predetermined condition may be that the smart pot 100 or plant related information is acquired or changed. The related information may be status information, a display attribute of the aura object 20, a display attribute of the character object 10, or touch information including a smart gesture.

More specifically, the predetermined condition may be that the status information is changed. Or the predetermined condition may be that the display attribute of the character object 10 is changed. Or the predetermined condition may be to receive a smart gesture. This will be described in more detail later.

The subject for determining whether a predetermined condition is satisfied may be the SmartPot 100, the server 200, or the smart device 300. [

The SmartPower 100 or the server 200 can inform the smart device 300 of satisfaction of the predetermined condition when the SmartPower 100 or the server 200 recognizes the satisfaction of the predetermined condition. Or the smart flower pot 100 or the server 200 may transmit information related to the predetermined condition to the smart device 300 together. However, the transmission of the related information may be transmitted to the smart device 300 after receiving the input of the push message selection from the user at a later time.

Thereafter, a push message indicating satisfaction of a predetermined condition may be output to the user (S4020).

The smart flower pot 100 or the server 200 that has obtained the predetermined condition may transmit a push message to the smart device 300 informing the user of the satisfaction of the predetermined condition. The smart device 300 receiving the push message or directly determining the satisfaction of the predetermined condition may display a message informing the user of the satisfaction of the predetermined condition.

The message displayed to the user may include information on satisfaction of a predetermined condition. The information included in the message may be information indicating that a predetermined condition is satisfied. The information included in the message may relate to what the predetermined predetermined condition is. The information included in the message may be related to information obtained or changed. The information included in the message may include what kind of information is acquired or changed or what information is obtained or changed.

The message displayed to the user may be a link that launches an application when selected. The message displayed to the user may be a link that, when selected, causes the application to run and display information associated with a predetermined condition. The message displayed to the user may include text, still images, moving images, graphic objects, and the like.

An input to select a push message from the user may then be received (S4030).

The smart device 300 may receive an input of a user selecting a push message. The input may be received via the touch sensor 322. The smart device 300 may then inform the smart flower pot 100 or the server 200 that the user's input is received. The smart device 300 may then receive information relating to predetermined conditions from the smart flower pot 100 or the server 200. [

Lastly, information related to a predetermined condition may be displayed (S4040).

The smart device 300 may display information related to a predetermined condition. The smart device 300 may execute the application to display information. The smart device 300 may display relevant information through the application screen. The smart device 300 may display status information, a display attribute of the aura object 20, a display attribute of the character object 10, or touch information including a smart gesture.

Hereinafter, the case where the state information is changed, the display attribute of the character object 10 is changed, and the case where the smart gesture is obtained will be described in detail as an example of a predetermined condition.

3.5.2. Push message due to status information change

The plant monitoring system 1000 can inform the user of the status information change in the form of a push message when the status information is changed.

First, when the system 1000 recognizes that the status information is changed, the smart device 300 may output a push message informing the user of the change of the status information. An input to select a push message from the user via the smart device 300 may then be received. Thereafter, the smart device 300 may display the aura object 20 reflecting the changed status information.

The output of the push message according to the change of the state information is necessary to efficiently manage plant cultivation. The status information reflects the cultivation environment of the plant. Therefore, the system 1000 can notify the user when the status information is changed, thereby guiding the management of the user.

The push message may be provided upon change of the status information. The push message may be provided upon change of all state information.

Alternatively, it may be provided only in some cases considering the type of the changed status information. For example, the push message may be provided only when the state information is changed from state information indicating that the environment information is in the optimal range to state information indicating that some of the environment information is out of the optimal range.

Alternatively, it may be provided only in some cases considering the level of the changed status information. For example, only when the state information is changed to state information indicating that the environment information has a significant difference from the optimum range, in the state information indicating that the environment information is outside the optimal range but in the vicinity of the optimum range, May be provided.

Thereafter, when a user input for selecting a push message is received, the smart device 300 can notify the server 200 that the user input has been received. The server 200 may transmit the display attribute of the aura object 20 calculated based on the changed status information to the smart device 300. [ The smart device 300 can display the aura object 20 according to the display attribute of the received aura object 20. [

24 is an example of a screen of the smart device 300 that outputs a push message.

As described above, the message displayed to the user through the screen of the smart device 300 may include various information related to satisfaction of a predetermined condition. The screen of Fig. 24 is merely an example of a screen for displaying the various information, and the display screen is not limited to the above embodiment.

Referring to FIG. 24 (a), information indicating that status information has been changed may be output to the screen of the smart device 300 that outputs a push message.

Referring to FIG. 24 (b), on the screen of the smart device 300 that outputs the push message, information indicating that the status information is changed to a dry state may be output. Also, a graphic object corresponding to a dry state may be output to the screen of the smart device 300. [

Through the above-described process, the user can be notified of the change of the status information and easily confirm the changed status information. Thus, plant management can be facilitated.

3.5.3. The push message according to the change of the display attribute of the character object 10

The plant monitoring system 1000 can inform the user in the form of a push message when the display attribute of the character object 10 is changed.

First, when the display attribute of the character object 10 is changed, the smart device 300 may provide a push message informing the user of the change. An input to select a push message from the user via the smart device 300 may then be received. Thereafter, the smart device 300 may display the character object 10 reflecting the changed display attributes.

The output of the push message in response to a change in the display attributes of the character object 10 may be an example of interaction between the user and the plant or smart pot 100. The output of the push message may be provided as a response to the user's affection towards the plant. The response to the degree of affection may be that the plant monitoring system 1000 displays a numerical value of the user's affection level and informs the user of the affinity with a graphical factor when the degree of affinity is high.

The push message may be provided at the time of changing the display attribute of the character object 10. The push message may be provided upon changing all of the display attributes of the character object 10. Alternatively, the push message may be provided only when a part of the display attribute is changed in consideration of the kind of the display attribute.

As described above, the display attribute acquisition of the character object 10 may be performed in any one of the smart pot 100, the server 200, and the smart device 300. [ For example, the server 200 may recognize that the display attribute of the character object 10 is changed due to increased affinity. The server 200 informs the smart device 300 and may request that the smart device 300 provide a push message to the user. Upon receiving the request, the smart device 300 may output a push message indicating that the display attribute of the character object 10 is changed.

Then, upon receiving a user input for selecting a push message, the smart device 300 can execute the application and display the changed display attributes of the character object 10. [

25 is an example of a screen of the smart device 300 that outputs a push message.

As described above, the message displayed to the user through the screen of the smart device 300 may include various information related to satisfaction of a predetermined condition. The screen of Fig. 25 is merely an example of a screen for displaying the various information, and the display screen is not limited to the above embodiment.

Referring to FIG. 25 (a), information indicating that the display attribute of the character object 10 has been changed may be output to the screen of the smart device 300 that outputs the push message.

Referring to FIG. 25 (b), the display attribute of the changed character object 10 may be output as a graphic object on the screen of the smart device 300 that outputs the push message.

Through the above-described process, the user can be notified of the change of the character object 10 according to his / her affection and can easily confirm the change.

3.5.4. Push message according to smart gesture

The plant monitoring system 1000 may provide a push message to the user in the smart device 300 when a smart gesture is input via the smart pot 100. [

The presentation of a push message according to a smart gesture can be an example of interaction of a user with a plant or smart pot 100. The provision of the push message according to the smart gesture is a response to the user's smart gesture input, and can be one of the methods for providing the user with information such as environmental information, status information, affinity information and the like. The user may also run the application directly to check the status of the plant. However, the provision of other push messages to the smart gesture can convey to the user the feeling that the user directly bids the plant by smartly tapping the potted plants (100) planted.

FIG. 26 shows an example of a screen of a smart device 300 that provides a push message according to a smart gesture.

Referring to FIG. 26, information informing that a smart gesture is recognized can be displayed on a screen of the smart device 300. In addition, graphic objects including the aura object 20 and the character object 10 may be displayed on the screen of the smart device 300. [

[0042] Referring to an order of an embodiment of a method in which a push message is provided according to a smart gesture, a smart gesture may first be sensed in the smart pot 100. [ Thereafter, the smart pot 100 may send a message to the server 200 indicating that a smart gesture is detected. The server 200 may then request the smart device 300 to provide the user with a push message asking whether to display information related to the smart pot 100 or the plant. The smart device 300 may output a push message asking whether to display information related to the smart pot 100 or the plant in response to the request. Upon receiving an input to select a push message from the user, the smart device 300 may receive information related to the smart pot 100 or plant from the server 200. The smart device 300 may execute the application and display information related to the smart pot 100 or plant.

It is to be noted that the above-described process is merely an embodiment, and the order of the processes described above may be changed, and the subject performing each step may be different from the process described above.

The information output by the smart device 300 may vary. The information may include information such as a strobe record, status information, a display attribute of the character object 10, and a display attribute of the aura object 20.

4. Plant Monitoring Methods

Hereinafter, some embodiments of scenarios that can be performed through the operation of each component of the plant monitoring system 1000 and the system 1000 described above will be described.

4.1. First monitoring method

Figure 27 is a flow diagram of one embodiment of a method for monitoring environmental information and status information in a smart device 300, provided by a plant monitoring system 1000 in accordance with the present invention.

Referring to FIG. 27, environmental information of the planted plant can be obtained (S5100). Thereafter, a state information determination criterion established according to the plant species may be obtained (S5200). The state information can be obtained based on the environment information using the state information determination reference (S5300). Then, the state information can be displayed through the aura object 20 (S5400).

The above-described process is merely an embodiment of the state information monitoring method, and thus the state information monitoring method is not limited to this embodiment. For example, the order of execution of each step may be changed. Specifically, environmental information can be obtained after the status information determination criterion according to plant species is acquired first. Or the subject of each step may be different. In particular, the acquisition of status information may be performed in one of the smartpot 100, the server 200, or the smart device 300.

In the following, each step will be described in detail.

First, the environmental information of the planted plant can be obtained (S5100).

The environmental information can be obtained through the environment information sensor 130 of the smart pot 100. The SmartPower 100 may record environment information in its own memory (not shown) or may transmit the environment information to the server 200 or the smart device 300.

Thereafter, a state information determination criterion established according to the plant species may be obtained (S5200).

The server 200 may first store the database of the status information determination criteria in the memory. The server 200 may then obtain information about the plant species by analyzing the user's input or plant photos uploaded by the user. The server 200 may then retrieve a status information criterion tailored to the plant species from the database. The server 200 may then transmit the state information determination criteria to the smart flower pot 100.

Then, the state information can be obtained based on the environment information using the state information determination reference (S5300).

The SmartPower 100 or the server 200 may perform an operation process based on the status information determination criterion and the environment information, and may acquire the status information.

Then, the state information can be displayed through the aura object 20 (S5400).

The server 200 can determine the display attribute of the aura object 20 based on the status information. The server 200 may transmit the display attribute of the aura object 20 to the smart device 300. [ The smart device 300 may display the display attributes of the aura object 20.

Through the above-described process, the user can monitor the environment in which the plant is grown in the smart pot 100 while checking the change of the graphic object, thereby providing the optimal environment for the plant.

4.2. Second monitoring method

28 is a flowchart of operations for displaying a strobe record according to recognition of a smart gesture provided by the plant monitoring system 1000 according to the present invention.

Referring to FIG. 28, the smart pot 100 may detect a stroking gesture (S6100). The server 200 can generate a stroking record when a stroking gesture is detected (S6200). After that, a smart gesture can be detected (S6300). Upon receipt of the request, the smart device 300 may provide a push message to the user (S6400). When the smart device 300 receives an input from the user for selecting a push message, the smart device 300 can display the stroking record (S6500).

The above-described process is merely an embodiment of the monitoring method corresponding to the smart gesture, so that the monitoring method corresponding to the smart gesture is not limited to this embodiment. For example, the order of execution of each step may be changed. Specifically, the smart device 300 may receive the stroking record from the server 200 before the push message output, or may be performed after the push message output.

In the following, each step will be described in detail.

First, the SmartPower 100 can sense the stroking gesture (S6100). The smart pot 100 may perform predetermined actions when a stroking gesture is sensed. The predetermined action may be to send a message to the server 200 informing of information about the stroking gesture. The information about the stroking gesture may include a stroking gesture acquisition time and a number of strokes gestures acquired.

The server 200 can generate a stroking record when a stroking gesture is detected (S6200). The server 200 may receive a message for the stroking gesture from the smartpot 100. Thereafter, the server 200 may generate a strobe record based on the message. The strobe record may include a time at which the stroked gesture is detected, an accumulated number of stroked gestures, a frequency of stroking gestures, and a degree of affection. The server 200 may store the writing of the strokes in the memory 220.

After that, a smart gesture can be detected (S6300). The smart pot 100 may sense the smart gesture through the touch sensor 120. [ When the smart gesture is detected, the smart pot 100 can perform a predetermined operation. The predetermined action may be for the smart pot 100 to inform the server 200 of the smart gesture detection. The server 200 receiving the smart gesture detection can perform a predetermined operation. The predetermined action may be to request the smart device 300 to provide a push message to the user.

Upon receipt of the request, the smart device 300 may provide a push message to the user (S6400). The push message may be a message asking the user whether to perform an operation to display a record of the stroked record.

After receiving the input of the user selecting the push message, the smart device 300 can display the strobe record (S6500).

Upon receiving the user input, the smart device 300 may notify the server 200 that the selection of the push message has been received. After that, the server 200 can retrieve the write history from the memory 220, and then transmit the write data to the smart device 300. The smart device 300 can display the received strobe record.

Through the above-described process, the user smartly taps the pots 100 so that he / she can check the history of his / her petting of the pots 100.

29 is a diagram of an embodiment in which a typing record is displayed on an application. It is assumed that the stroking record of Fig. 29 is the same as the stroking record of Fig.

The smart device 300 can output a strobe record on the screen on which the application is running. The stroking record may include information on the date, time, affection and growth properties of the stroking gesture detection. The bar bar means the timeline. On the right side of the timeline, the time information in which the stroking gesture is detected can be displayed. On the left side of the time line, the date and time at which the growth attribute is changed can be displayed.

4.3. Third monitoring method

It has been described that a plurality of smart pots 100 and smart devices 300 can be linked to one server 200. [

30 shows information about the smart pot 100 interlocked with the smart device 300 and information about the smart pot 100 interlocked with other smart devices 300 in one smart device 300 Lt; / RTI > is an illustration of an embodiment of an application screen.

The server 200 may transmit not only the information about the smart pots 100 bound to one smart device 300 but also information about the other smart pots 100 to the one smart device 300. [ The information about the other smart pots 100 may include at least one of a display property of the aura object 20-2 acquired according to the environment information sensed by the other smart pots 100, And a display attribute of the character object 10-2 obtained in accordance with the attribute information.

An application driven by one smart device 300 may include a character object 10-1 and an aura object 20-1 associated with the smart flower pot 100 bound to the one smart device 300, The character object 10-2 and the aura object 20-2 associated with the other smart flower pots 100 bound to the smart flower pot 300 may be displayed.

The server 200 can group and manage the IDs of the smart pots 100 and the smart devices 300 associated with the character object 10 and the aura object 20 displayed together.

The smart device 300 may receive input from a user to include the smart pot 100 or the smart device 300 in one group. The smart device 300 may transmit the input to the server 200. [ The server 200 receives the input and can thus manage the smart device 300 or the smart flower pot 100 in the requested group.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, It will be apparent to those skilled in the art that changes or modifications may fall within the scope of the appended claims.

10 Character Objects
20 aura object
100 smart pots
200 servers
300 smart devices
1000 Plant Monitoring System

Claims (12)

Smart potted plants that are planted and interlocked with smart devices that drive applications related to the planted plants,
A potting case for providing a space for accommodating the cultivation soil or the culture liquid for culturing the plant therein;
A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case;
A second touch sensor installed at a lower portion of the flowerpot case so as to surround the flowerpot case along the circumference of the flowerpot case and spaced apart from the first touch sensor by a predetermined interval; And
A first touch input is obtained from the user through the first touch sensor, a second touch input is obtained from the user through the second touch sensor, a second touch input is performed within a predetermined time after the first touch input is acquired, And a second operation associated with the application when either one of the first touch input or the second touch input is successively acquired within a predetermined time, And a control unit
Smart potted plants.
The method according to claim 1,
And a communication unit for communicating with at least one of the smart device and a server operatively associated with the smart device with respect to the application,
Wherein the first operation is for the control unit to transmit a first message related to the application via the communication unit,
Wherein the second action is that the control unit transmits a second message associated with the application different from the first message via the communication unit
Smart potted plants.
Smart potted plants that are planted and interlocked with smart devices that drive applications related to the planted plants,
A pollen case for providing a space in which a cultivated soil or a culture liquid is received;
A first touch sensor and a second touch sensor provided in the flowerpot case and spaced apart from each other in the vertical direction;
A communication unit for communicating with a server associated with the smart device in association with the application; And
Acquiring a first touch input from a user through the first touch sensor, acquiring a second touch input from the user through the second touch sensor,
When a second touch input is obtained within a first predetermined time after acquiring the first touch input, transmits to the server a first message requesting a record relating to the execution of the stroking gesture through the communication unit,
When the first touch input or the second touch input is successively acquired within a second predetermined time, includes affinity information on the plant calculated based on the stroking gesture to the smart device through the communication unit To the server, a second message requesting transmission of a push message relating to the application
Smart potted plants.
The method of claim 3,
The first touch sensor is installed above the second touch sensor in the flowerpot case,
The pollen case may be arranged such that a circumference of a portion where the first touch sensor is installed is shorter than a circumference of a portion where the second touch sensor is installed
Smart potted plants.
5. The method of claim 4,
The smart flower pot may further comprise an illuminance sensor,
The pollen case has a larger circumference at the lower portion than the upper portion,
The illuminance sensor is disposed at a lower portion of the flowerpot case, the periphery of which is larger than the upper portion of the flowerpot case to secure a light receiving range
Smart potted plants.
5. The method of claim 4,
Wherein the first touch sensor and the second touch sensor are installed in the flowerpot case so as to surround only a part of the perimeter of the flowerpot case,
A first area where the flowerpot case is not surrounded by the first touch sensor at a location where the first touch sensor is installed and a second area where the flowerpot case is located at a location where the second touch sensor is installed And the second non-enclosed area is located in the same direction when viewed from the top of the flowerpot case
Smart potted plants.
The method according to claim 6,
The smart flower pot further includes an illuminance sensor whose light receiving direction is directed in the same direction
Smart potted plants.
The method according to claim 6,
The smart flower pot may further include an output section that outputs a visual signal but whose emission direction is directed in the same direction
Smart potted plants.
A first touch sensor installed on an upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, A communication unit for communicating with a smart flower pot and a smart device including a first touch sensor and a second touch sensor spaced apart from each other by a predetermined gap at upper and lower intervals;
A memory for recording information; And
When the second touch input is obtained from the second touch sensor within a predetermined time after the first touch input of the smart flower pot is obtained, a request is made to record a history of the stroking gesture being performed Receiving a first message through the communication unit, writing in the memory that a stroking gesture has been performed according to the first message,
Wherein the first touch input or the second touch input is successively acquired within a predetermined time, and the pushing of the application including the affinity information on the plant calculated on the basis of the stroking gesture by the smart device And a controller for receiving a second message requesting transmission of the message through the communication unit and requesting the smart device to provide the push message to the user according to the second message,
server.
A first touch sensor installed on an upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, A communication unit communicating with at least one of a smart flower pot or a server including a first touch sensor and a second touch sensor spaced apart from the first touch sensor by a predetermined interval;
An output unit for displaying information; And
When the second touch input is obtained from the second touch sensor within a predetermined time after the first touch input of the smart flower pot is obtained, a request is made to record a history of the stroking gesture being performed Receiving a record of the recorded stroking gesture according to the first message,
Wherein the first touch input or the second touch acquisition is continuously obtained within a predetermined time, and the affinity information for the plant calculated based on the stroking gesture Receiving a second message requesting transmission of a push message through the communication unit and providing the push message to a user according to the second message;
Smart devices.
A potting case for providing a space for accommodating the cultivation soil or the culture liquid for cultivating the plant therein; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor spaced apart from the first touch sensor by a predetermined distance in the vertical direction, the method comprising the steps of:
Obtaining a first touch input from a user through the first touch sensor;
Obtaining a second touch input from the user through the second touch sensor;
Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And
And performing a second operation associated with the application when any one of the first touch input or the second touch input is successively acquired within a predetermined time
Plant monitoring method.
A potting case for providing a space for accommodating the cultivation soil or the culture liquid for cultivating the plant therein; A first touch sensor installed on the upper part of the flowerpot case so as to surround the flowerpot case along a circumferential direction of the flowerpot case and a flowerpot case surrounding the flowerpot case along a circumferential direction of the flowerpot case at a lower portion of the flowerpot case, And a second touch sensor spaced apart from the first touch sensor by a predetermined distance in a vertical interval, the method comprising the steps of:
Obtaining a first touch input from a user received via the first touch sensor;
Obtaining a second touch input from a user received via the second touch sensor;
Performing a first operation associated with the application when a second touch input is obtained within a predetermined time after acquisition of the first touch input; And
And performing a second operation associated with the application when any one of the first touch input or the second touch input is successively acquired within a predetermined time
Plant monitoring method.

Images