KR102580770B1 - Intelligent smart plant care system combined with smart soil condition sensor and beacon function - Google Patents

Abstract

The intelligent smart plant care system, which combines a smart soil condition sensor and a beacon function, is placed at regular intervals in the soil where plants are growing, measures soil moisture, and sends out the measured data periodically at preset intervals. Each is assigned to a soil condition sensor and a plurality of smart soil condition sensors, and a plurality of automatic waterers and plant care applications are installed to supply moisture to the soil under the control of the assigned smart soil condition sensor. It is characterized by including a portable terminal that receives the transmitted data and visually displays the soil condition.

Description

Intelligent smart plant care system combined with smart soil condition sensor and beacon function}

The present invention relates to an intelligent smart plant care system, and more specifically, to an intelligent smart plant care system combining a smart soil condition sensor and a beacon function.

In general, many flower pots are used for indoor air purification and decoration, such as in living rooms or company offices.

Additionally, in the agriculture and flower fields, plants are managed using agricultural flower pots.

Moisture management is important for the maintenance and growth of plants, but because it is difficult to note or remember each pot individually, there are often cases where plant growth is inhibited.

In addition, when supplying moisture to a flower pot, there are cases where too much water is supplied and the fertilizer water from the flower pot overflows from the flower pot holder onto the floor of the living room or office, making it very messy.

KR 10-1583126 B

The present invention was proposed to solve the above technical challenges, and provides an intelligent smart plant care system that combines a smart soil condition sensor and a beacon function to visually inform users of cultivation environment data.

According to an embodiment of the present invention to solve the above problem, a plurality of smart soils are placed at regular intervals in the soil in which plants are growing, measure the soil moisture content, and periodically transmit the measured data at preset intervals. Each is assigned to a condition sensor and a plurality of smart soil condition sensors, and a plurality of automatic waterers and plant care applications are installed to supply moisture to the soil under the control of the assigned smart soil condition sensor, and are transmitted from the plurality of smart soil condition sensors. An intelligent smart plant care system is provided that includes a portable terminal that receives soil data and visually displays soil conditions.

In addition, the present invention further includes a management server that learns data from a plurality of smart soil condition sensors transmitted from a portable terminal through a deep learning algorithm using an artificial neural network to propose recommended temperature and recommended humidity and predict growth deficiency. It is characterized by

In addition, the plurality of smart soil condition sensors included in the present invention are characterized by a built-in beacon module that periodically transmits a short-range wireless signal in a certain band at a preset period using a Bluetooth communication method.

In addition, the plurality of smart soil condition sensors included in the present invention are characterized by measuring soil moisture content, soil temperature, electrical conductivity (EC), and acidity (pH).

The intelligent smart plant care system according to an embodiment of the present invention has the advantage of visually informing the user of cultivation environment data by combining a smart soil condition sensor and a beacon function.

1 is a configuration diagram of an intelligent smart plant care system 1 according to an embodiment of the present invention.
Figure 2 is an example diagram of an intelligent smart plant care system (1)
Figure 3 is a first example of a plant care application.
Figure 4 is a second example of a plant care application.
Figure 5 is a third example of a plant care application
Figure 6 is a fourth example of a plant care application
Figure 7 is a conceptual diagram of calculating the optimal recommended soil moisture.

Hereinafter, in order to explain the present invention in detail so that a person skilled in the art can easily implement the technical idea of the present invention, embodiments of the present invention will be described with reference to the accompanying drawings.

Figure 1 is a configuration diagram of an intelligent smart plant care system 1 according to an embodiment of the present invention, and Figure 2 is an exemplary diagram of the intelligent smart plant care system 1.

The intelligent smart plant care system 1 according to this embodiment includes only a brief configuration to clearly explain the technical idea to be proposed.

Referring to FIGS. 1 and 2, the intelligent smart plant care system 1 includes a smart soil condition sensor 100, an automatic waterer 200, a portable terminal 300, and a management server 400.

The main operations of the intelligent smart plant care system (1) configured as above are as follows.

A plurality of smart soil condition sensors 100 are placed at regular intervals in the soil where plants are growing, measure the soil moisture content, and periodically transmit the measured data at preset intervals. Moisture measurement of the smart soil condition sensor 100 can be performed through an FDR (Frequency Domain Reflectometry) sensor module.

The plurality of smart soil condition sensors 100 are equipped with a beacon module that periodically transmits short-range wireless signals in a certain band at preset intervals using the Bluetooth communication method.

Additionally, depending on the embodiment, the smart soil condition sensor 100 may be configured to measure not only soil moisture but also soil temperature, electrical conductivity (EC), and acidity (pH).

The plurality of automatic waterers 200 are respectively assigned to a plurality of smart soil condition sensors 100 and perform an operation of supplying moisture to the soil under the control of the assigned smart soil condition sensor. That is, when the smart soil condition sensor 100 detects that the moisture content is lower than the preset standard value, it controls the automatic waterer 200 to supply a predetermined set moisture to the soil.

For reference, if the smart soil condition sensor 100 is equipped with a temperature sensor, the set amount of moisture supplied to the soil is automatically trimmed according to the temperature. In other words, if the temperature is high, the amount of evaporation may increase, so the system is automatically set to supply more moisture as the soil temperature rises. In other words, if 100 units of moisture is set to be supplied based on 24 degrees Celsius, it can be automatically adjusted to supply 120 units of moisture at 30 degrees Celsius and 80 units of moisture at 18 degrees Celsius.

Figure 3 is a first example of a plant care application, Figure 4 is a second example of a plant care application, Figure 5 is a third example of a plant care application, and Figure 6 is a fourth example of a plant care application. am.

3 to 6, the portable terminal 300 has a plant care application installed and receives data transmitted from a plurality of smart soil condition sensors 100 to visually display the soil condition.

Here, a portable terminal is a general term for devices that a user can carry and use, such as a mobile phone, smartphone, smart pad, etc. In this embodiment, the description will be made assuming a portable terminal consisting of a smartphone.

In other words, the plant care application can display the remaining battery capacity of the smart soil condition sensor 100 and the moisture content of the soil. Additionally, the plant care application can display a menu for registering the new smart soil condition sensor 100 to the user.

In addition, the plant care application can provide information about past history, such as the amount of moisture in the flower pot managed by each smart soil condition sensor 100. Additionally, the type of flower pot can be visually displayed. If an additional camera is attached to the smart soil condition sensor 100, the plant care application can continuously update and display the type of pot in real-time video.

For reference, the plant care application may directly control the automatic waterer 200 by transmitting control data to the smart soil condition sensor 100.

The management server 400 learns data from a plurality of smart soil condition sensors 100 transmitted from the portable terminal 300 through a deep learning algorithm using an artificial neural network to suggest recommended temperature and recommended humidity and can predict growth deficiency. there is. This information is fed back to the plant care application of the portable terminal 300.

Figure 7 is a conceptual diagram of calculating the optimal recommended soil moisture.

Referring to FIG. 7, the management server 400 provides “soil moisture content, soil temperature, electrical conductivity (EC) and acidity (pH), farm growth, environmental data, weather data, climate by year, and personal environmental data.” Learning is conducted periodically through an intelligent learning engine. In other words, the optimal soil moisture content can be predicted based on learned data and trends.

Here, the artificial neural network is composed of an input layer, a hidden layer, and an output layer. The activation function of the hidden layer uses the ELU function, and the activation function of the output layer of the hidden layer uses the tanh function. The loss function uses mean_squared_error, and the optimizer uses Adam optimizer.

In other words, the intelligent smart plant care system (1) utilizes the farm's accumulated growth/cultivation environment data and public weather data (government's annual rainfall/moisture data, etc.), and links/processes personal moisture/cultivation environment data. It can be designed to provide optimal moisture conditions.

For reference, a sensor may be provided to detect blockage of the flow path of the automatic waterer 200.

That is, the automatic waterer 200 may be equipped with a first Doppler sensor and a second Doppler sensor. In a Doppler detection sensor, when a microwave signal hits a moving target, the frequency of this signal changes due to the Doppler effect. If movement occurs, there is a phase change in the microwave signal according to the movement. The Doppler detection sensor consists of a pair of transmitting and receiving units, and can be configured to adjust the detection distance by adjusting the frequency or output power.

The first Doppler sensor and the second Doppler sensor are provided to detect the flow of water output to the first output valve along the internal space, that is, the pipe-shaped flow path of the automatic waterer 200.

In other words, as stuck matter accumulates in the flow path, the flow of water may decrease, so by detecting this, the internal stuck state can be indirectly determined.

The first Doppler sensor and the second Doppler sensor are arranged diagonally opposite each other in a pipe-shaped flow path, and each independently measures the flow of nutrient solution in the flow path and transmits the measurement information to the plant care application. The first Doppler sensor and the second Doppler sensor may use transmission signals having different frequencies.

At this time, the plant care application collects information from both sensors and operates to trust the measurement information only when the flow of nutrient solution is detected at the same time. This configuration can prevent erroneous detection of flows in other adjacent areas within the maximum measurement distance of the Doppler sensor.

The intelligent smart plant care system according to an embodiment of the present invention has the advantage of visually informing the user of cultivation environment data by combining a smart soil condition sensor and a beacon function.

The intelligent smart plant care system (1) can create a new platform for growing plants by reflecting user needs through product sales in the market, and is a universal and easy-to-use sensor that can be used in open fields, farms, orchards, etc. can be applied.

In conjunction with a plant management system combined with 5G, a system that can narrow the distance between plants and people can be applied in urban farms, homes, and farms.

As such, a person skilled in the art to which the present invention pertains will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive. The scope of the present invention is indicated by the claims described below rather than the detailed description above, and all changes or modified forms derived from the meaning and scope of the claims and their equivalent concepts should be interpreted as being included in the scope of the present invention. do.

100: Smart soil condition sensor
200: Automatic waterer
300: Portable terminal
400: Management server

Claims (4)

A plurality of smart soil condition sensors placed at regular intervals in the soil where plants are growing, measure the soil moisture content, and periodically transmit the measured data at preset intervals;
A plurality of automatic waterers each assigned to the plurality of smart soil condition sensors and supplying moisture to the soil under the control of the assigned smart soil condition sensor, and automatically trimming a set amount of moisture supplied to the soil according to the temperature of the soil;
A portable terminal installed with a plant care application and receiving data transmitted from the plurality of smart soil condition sensors to visually display soil condition; and
A management server that learns data from the plurality of smart soil condition sensors transmitted from the portable terminal through a deep learning algorithm using an artificial neural network to suggest recommended temperature and recommended humidity and predict growth deficiency; Including,
The automatic waterer includes a first Doppler sensor and a second Doppler sensor, which are arranged diagonally opposite each other in the pipe-shaped flow path of the automatic waterer to independently measure the flow of nutrient solution in the flow path and use transmission signals with different frequencies. 2 Intelligent smart plant care system characterized by having a Doppler sensor.
delete According to paragraph 1,
The plurality of smart soil condition sensors,
An intelligent smart plant care system characterized by a built-in beacon module that periodically transmits short-range wireless signals in a certain band at preset intervals using the Bluetooth communication method.
According to paragraph 1,
The plurality of smart soil condition sensors,
An intelligent smart plant care system that measures soil moisture, soil temperature, electrical conductivity (EC), and acidity (pH).