KR102451509B1 - Smart Soil Management System - Google Patents

Abstract

The present invention relates to a smart soil management system, which can also improve a carbon neutral effect. The smart soil management system comprises: a producer terminal group (100g) including a plurality of producer terminals (100); a network (200); a smart soil management server (300) including a transceiving unit (310), a control unit (320), and a database (330); and a big data server (400).

Description

Smart Soil Management System

The present invention relates to a smart soil management system, and more specifically, to obtain data on which parts to supplement for farmland soil information and climate information of farmland that an agricultural producer wants to cultivate, and to target land across the country. In addition to making it possible to understand the current situation, it is also possible to determine the price of each agricultural product and when to grow what crops at any time by checking how much yield can be increased by cultivating which crops at what time, so that ultimately the amount of goods transported can be checked. It is about a smart soil management system to enable crop planning production through

Currently, there are no specific data on farmland soil information and climate information for farmland in Korea. Accordingly, it is difficult to predict the yield and transport volume according to crops. The price of agricultural products is repeating rapid fluctuations, and recently, there is a problem in that the planned production cannot proceed when growing crops, such as the price soaring due to a decrease in the production and distribution of green onion, a vegetable used by the whole nation.

In addition, in the case of agricultural soil, it is difficult to select and cultivate an appropriate crop because the soil composition and moisture inside it are not grasped. It is not possible.

Meanwhile, technologies for efficiently managing soil to increase agricultural production have been developed and proposed.

For example, in the Republic of Korea Patent Application No. 10-2002-0054276 (2002.09.09), "System and method for managing a rich soil", the central processing unit is an automated device according to the internal state of the soil. By controlling these fields, a separate operating program is not used, and it has the effect of maintaining the soil in an optimal state for crop growth even without computer expertise.

In addition, the Republic of Korea Patent Application No. 10-2010-0105534 (October 27, 2010) No. "The soil nutrients management system for using a mobile vehicle" is It relates to a system and method for inspecting the composition of soil and automatically supplying nutrients.

In addition, the Republic of Korea Patent Application No. 10-2016-7006901 (2014.08.14) No. "MANAGEMENT SYSTEM AND METHOD FOR MANAGING SOIL TREATMENT SYSTEMS" is for managing a soil treatment business. In the system 10 for the present invention, the injection device 12 is operable to inject the soil treatment agent into the soil under high pressure. A control system 92 is associated with the injection device 12 and is configured to collect data during operation of the injection device 12 . The data management system 801 is configured to receive data collected by the control system 92 of the injection device 12 . Here, the data management system 801 generally includes a database for storing the collected data, and the data management system relates to technology accessible by the business entity for reviewing the collected data.

In addition, Korean Patent Application No. 10-2007-0023878 (2007.03.12) No. "System for automatic control of a greenhouse and method for management of a greenhouse by using soil and environmental sensors "using the sensor of soil and atmospheric phenomena" is about using the sensing data measured by sensors inside and outside the greenhouse to help producers create optimal environmental conditions for crop growth and to show the growing environment of crops to consumers. .

However, with these conventional technologies, it is difficult for agricultural producers to obtain data on what part to supplement for farmland soil information and climate information of the farmland they want to cultivate, and it is difficult to understand the current status of land across the country. It is possible to predict in advance which crops can be cultivated at what time and how much yield can be raised, so that it is possible to understand in advance which crops are suitable to be grown at what time for each agricultural product and the prices of agricultural products in advance. There are limitations to enabling proper crop planning production.

Korean Patent Application No. 10-2002-0054276 (2002.09.09) "System and method for managing a rich soil" Korean Patent Application No. 10-2010-0105534 (2010.10.27) "The soil nutrients management system for using a mobile vehicle" Korean Patent Application No. 10-2016-7006901 (2014.08.14) "MANAGEMENT SYSTEM AND METHOD FOR MANAGING SOIL TREATMENT SYSTEMS" Republic of Korea Patent Application No. 10-2007-0023878 (2007.03.12) No. "System for automatic control of a greenhouse and method for management of a greenhouse by using the soil and environmental sensors sensor of soil and atmospheric phenomena)"

The present invention is to solve the above problems, and to provide a soil management system that enables agricultural producers to acquire data on which parts to supplement with respect to farmland soil information and climate information of the farmland they want to cultivate. it is for

In addition, the present invention makes it possible not only to grasp the current status of land across the country, but also to determine how much yield can be raised when which crops are cultivated at what time, so that each agricultural product is also grown at what time. This is to provide a soil management system that can properly control supply and demand for each crop by enabling planned production of crops through confirmation of the volume of goods transported in the end, as it can also grasp the prices of agricultural products.

In addition, by making a database of soil information on farmland, when agricultural producers want to change crops or grow new varieties, they can identify necessary nutrients in advance and compare them with current soil information to find out what nutrients are lacking. Fertilization can be done, and purchases can be made using a supplier (eg, a manufacturer) of agricultural materials such as fertilizer and a platform application, etc. By analyzing and providing a list of algorithms based on big data of artificial intelligence (AI) It is to provide a soil management system.

In addition, by providing customized information for each farmland so that an appropriate amount of fertilizer can be applied, it is possible to reduce agricultural costs (agricultural costs), and to reduce the greenhouse effect by preventing excessive use of fertilizers, thereby improving the carbon-neutral effect. It is intended to provide a soil management system with

However, the objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object, the present invention

producer terminal 100; and smart soil management server 300; Including, the smart soil management server 300,

After access through the network 200 of the producer terminal 100, GPS location information and crop condition information (including cultivation classification information, number of cultivation information, and cultivation medium information) of the farmland to be cultivated further includes A cropping analysis module 324 that receives the transceiver 310 to receive a cultivation analysis request from the producer terminal 100, and analyzes condition information for growth of agricultural products, which is cultivation classification information to be cultivated included in the cultivation analysis request. ); It provides a smart soil management system comprising a.

In an embodiment of the present invention, the smart soil management server 300 includes a soil information collection module 321 and a crop condition information collection module 322 for collecting soil information, crop condition information, and climate information required for cultivation analysis, respectively. , characterized in that it further comprises a climate information collection module (323).

In addition, in an embodiment of the present invention, farmland soil information [soil moisture, pH, electrical conductivity, organic matter and nitrate nitrogen and ammonia nitrogen], crop status information [cultivation classification information (including cabbage, apple, radish, pear, lettuce) and number of cultivation, and cultivation medium information (seeds, seedlings, seedlings) etc.], climate information [including temperature, humidity, wind speed, and illuminance of each period (including year, month, week, day)] is collected in the database 330 as “smart soil management information” for each unit area It is characterized in that it is integrated and stored by the module 323 .

In addition, in one embodiment of the present invention, the crop condition analysis module 324 collects the temperature, humidity, wind speed, and illuminance included in the climate information for each unit area after a preset time corresponding to each smart soil management information has elapsed. It is characterized in that the "transport volume (agricultural product production) compared to the number of cultivation by each cultivation medium" of crop information by cultivation during the period corresponding to the reference time is collected from farmers across the country including the producer terminal 100 through on/offline do it with

In addition, in one embodiment of the present invention, the crop condition analysis module 324 is a database 330 together with a unit area for classifying smart soil management information for "amount of trade (agricultural product production) compared to the number of cultivation by cultivation medium" as metadata. ) is characterized in that it is stored on the

The smart soil management system according to an embodiment of the present invention enables agricultural producers to acquire data on which parts to supplement with respect to farmland soil information and climate information of the farmland they want to cultivate, and a central information processing agency and By using the network communication of the producer, it is possible to check and store information through the smart device of the producer.

In addition, the smart soil management system according to another embodiment of the present invention makes it possible not only to grasp the current status of land across the country, but also to check how many crops can be cultivated at what time to increase the yield. Each agricultural product also has the effect of properly regulating supply and demand for each crop by enabling planned production of crops through checking the volume of goods, as the price of agricultural products can be grasped when cultivating any crop at any time.

In addition, by systematically databaseizing the soil information of farmland, when agricultural producers want to change crops or grow new varieties, or when they want to proceed with 2 or 3 crops, Comparison with current soil information enables fertilization of insufficient nutrients, and enables purchases to be made using suppliers (eg manufacturers) of agricultural materials such as fertilizers and platform applications, etc. By analyzing and providing a list of algorithms based on artificial intelligence (AI) big data based on the taste, personality, characteristics, and other factors of farmhouse analysis data, it is possible to increase agricultural production, and for non-skilled farmers such as returning farmers It is also effective in providing information so that high yields can be achieved without difficulty.

In addition, by providing customized information for each farmland so that an appropriate amount of fertilizer can be applied, it is possible to reduce agricultural costs (agricultural costs), and to reduce the greenhouse effect by preventing excessive use of fertilizers, thereby improving the carbon-neutral effect. there are advantages to

1 is a view showing a smart soil management system 1 according to an embodiment of the present invention.
2 is a block diagram showing the components of the smart soil management server 300 of the smart soil management system 1 according to an embodiment of the present invention.
3 is a block diagram showing the components of the control unit 320 of the smart soil management server 300 of the smart soil management system 1 according to an embodiment of the present invention.
4 is a flowchart illustrating a soil management process by the smart soil management system 1 according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a detailed description of a preferred embodiment of the present invention will be described with reference to the accompanying drawings. In the following description of the present invention, if it is determined that a detailed description of a related well-known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

In the present specification, when any one component 'transmits' data or signal to another component, the component may directly transmit the data or signal to another component, and through at least one other component This means that data or signals can be transmitted to other components.

1 is a view showing a smart soil management system 1 according to an embodiment of the present invention. Referring to FIG. 1 , the smart soil management system 1 includes a producer terminal group 100g consisting of a plurality of producer terminals 100 , a network 200 , a smart soil management server 300 and a big data server 400 . may include

Here, the network 200 is a high-speed backbone network of a large-scale communication network capable of large-capacity, long-distance voice and data services, and may be a next-generation wired or wireless network for providing the Internet or high-speed multimedia services. When the network 200 is a mobile communication network, it may be a synchronous mobile communication network or an asynchronous mobile communication network. As an example of the asynchronous mobile communication network, there may be a wideband code division multiple access (WCDMA) type communication network. In this case, although not shown in the drawing, the network 200 may include a Radio Network Controller (RNC). Meanwhile, although the WCDMA network is taken as an example, it may be a 3G LTE network, a 4G network, other next-generation communication networks such as 5G, and other IP-based IP networks. The network 200 may include a producer terminal group 100g consisting of a plurality of producer terminals 100 , a smart soil management server 300 and a big data server 400 . Signals and data between other systems serves to communicate with each other.

2 is a block diagram showing the components of the smart soil management server 300 of the smart soil management system 1 according to an embodiment of the present invention. 3 is a block diagram showing the components of the control unit 320 of the smart soil management server 300 of the smart soil management system 1 according to an embodiment of the present invention. 4 is a flowchart illustrating a soil management process by the smart soil management system 1 according to an embodiment of the present invention. First, referring to FIG. 4 , the smart soil management system 1 performs a soil information collection process (S11), a crop information collection process (S12), a climate information collection process (S13), a crop analysis process (S14), and a trade volume analysis process. (S15), and a carbon-neutral analysis process (S16) may be performed.

To this end, referring to FIGS. 2 and 3 , the smart soil management server 300 includes a transceiver 310 , a control unit 320 , and a database 330 , and the control unit 320 includes a soil information collection module 321 . ), a crop condition information collection module 322 , a climate information collection module 323 , a crop condition analysis module 324 , and a trade volume analysis module 325 .

The soil information collection module 321 requests the GPS location information and farmland soil information from the big data server 400 through the network 200 in a state where the GPS location information and farmland soil information are stored on the big data server 400 . After controlling the transceiver 310 to do this, the received GPS location information and the GPS location information among the farmland and soil information are classified by unit area of the country and collected on the database 330 as farmland soil information for each unit area. can

On the other hand, the farmland soil information received by the soil information collection module 321 may include soil moisture, pH, electrical conductivity, organic matter, nitrate nitrogen, ammonia nitrogen, and the like.

Here, the GPS location information and farmland soil information collected by the big data server 400 are collected from the soil information collection device and provided to the big data server 400 through the network 200, and the soil moisture, pH of the farmland soil information , electrical conductivity, organic matter, nitrate nitrogen, and ammonia nitrogen can be collected through the soil moisture sensor, organic matter sensor, pH sensor, nitrate nitrogen sensor, and ammonia nitrogen sensor provided in the soil information collection device. have.

The crop condition information collection module 322 requests the big data server 400 to request the GPS location information and the crop condition information from the big data server 400 through the network 200 in a state where the GPS location information and farmland and soil information are stored on the big data server 400 . After controlling the transceiver 310 , the received GPS location information and the GPS location information among the harvest information may be collected on the database 330 as harvesting information for each unit area divided by unit area of the country.

Meanwhile, the crop status information received by the crop status information collection module 322 includes cultivation classification information (cabbage, apple, radish, pear, lettuce, etc.), cultivation number information, and cultivation medium information (seeds, seedlings, seedlings, etc. information). may include

Here, the GPS location information and crop condition information collected by the big data server 400 are collected from the cultivation information collection device and provided to the big data server 400 through the network 200, and the cultivation information collection device is the producer terminal 100. Alternatively, it may be formed as a separate terminal device, and image information acquired from the terminal device based on camera image recognition and a plurality of crops (cabbage, apple, radish, pear, lettuce, etc.) pattern information provided in the cultivation classification DB, preset By comparing the image pattern with the crop pattern information inclined at each angle, the cultivation classification information corresponding to the crop is extracted from the image information, and a plurality of cultivation media provided in the divided cultivation medium DB based on each extracted cultivation classification information By comparing the image pattern with the medium (seed, seedling, seedling, etc. information) pattern information and the cultivation medium pattern information inclined at each preset angle, the cultivation medium is extracted from the image information, and the number of each extracted cultivation medium is calculated. By doing so, information on the number of cultivations can be obtained.

The climate information collection module 323 transmits and receives the meteorological area information and climate information to the big data server 400 through the network 200 in a state where the weather area information and climate information are stored on the big data server 400 . After controlling the unit 310, with respect to the meteorological area information among the received meteorological area information and climate information, the soil information collection module 321 and the crop condition information collection module 322 are divided for use in unit areas of the country and Through matching of , it is possible to collect on the database 330 as climate information for each unit area divided by each unit area.

On the other hand, the climate information received by the climate information collection module 323 is temperature, humidity, and wind speed during each period for each unit area of the country divided for use in the soil information collection module 321 and the crop condition information collection module 322 . , illuminance, etc. may be included.

And, the climate information collection module 323 for meteorological area information, when matching with unit areas of the country divided for use in the soil information collection module 321 and the crop condition information collection module 322, the meteorological area information is In the case of including unit area information of the whole country, meteorological area information is used as unit area information. When generating climate information for each unit area, it is desirable to use the average value.

As described above, farmland soil information [soil moisture, pH, electrical conductivity, organic matter, and nitrate status for each unit area generated by the soil information collection module 321, the crop condition information collection module 322, and the climate information collection module 323] Nitrogen, ammonia nitrogen, etc.], crop status information [cultivation classification information (cabbage, apple, radish, pear, lettuce, etc.) and cultivated number information, and cultivation medium information (seeds, seedlings, seedlings, etc.), climate information [during each period Temperature, humidity, wind speed, illuminance, etc. of (year, month, week, day, etc.)] are integrated and stored in the database 330 by the climate information collection module 323 as "smart soil management information" for each unit area. can be

After a preset time corresponding to each smart soil management information elapses, the crop condition analysis module 324 collects the temperature, humidity, wind speed, illuminance, etc. included in the climate information for each unit area. The unit area that classifies smart soil management information by collecting “transportation volume (agricultural product production) relative to the number of cultivation by cultivation medium” of crop status information by on/offline from farmers across the country including the producer terminal 100 is metadata. may be stored together in the database 330 .

Thereafter, the crop condition analysis module 324 provides GPS location information and crop condition information (cultivation classification information, number of cultivation information) of the farmland to be cultivated in addition after access through the network 200 of the producer terminal 100. , cultivation medium information, etc.) may receive the transceiver 310 to receive the cultivation analysis request including the producer terminal 100 from.

Thereafter, the cropping analysis module 324 may analyze the condition information for growth of agricultural products, which is the cultivation classification information to be cultivated included in the cultivation analysis request.

To this end, the crop analysis module 324 extracts "smart soil management information" divided into the same unit area as the current producer GPS location information, and farmland soil information [soil moisture, pH] included in the extracted smart soil management information. , electrical conductivity, organic matter and nitrate nitrogen, ammonia nitrogen, etc.] and climate information [temperature, humidity, wind speed, illuminance, etc. for each period (year, month, week, day, etc.)] are used to collect each climate information. Smart soil management information corresponding to the unit area that produced agricultural products, which is the cultivation classification information to be cultivated included in the request for cultivation analysis while having the most similar numerical value for each divided period (year, month, week, day, etc.) It can be extracted as "representative smart soil management information".

Thereafter, the cropping analysis module 324 extracts the "transport volume (agricultural product production) compared to the number of cultivation by cultivation medium" of the "representative smart soil management information" and provides it to the producer terminal 100 through the network 200. Transmitting/receiving unit ( By controlling the 310), it is possible to predict the yield by the producer terminal 100.

In addition, the crop condition analysis module 324 provides each parameter of farmland soil information of "representative smart soil management information" [soil moisture, pH, electrical conductivity, organic matter and nitrate nitrogen, ammonia nitrogen, etc.], and climate information For each parameter of [Temperature, humidity, wind speed, illuminance, etc. for each period (month, week, day, etc.)] It is possible to control the transceiver 310 to receive " through a request to the big data server 400 .

After that, the crop condition analysis module 324 performs the [soil moisture, pH, electrical conductivity, organic matter, nitrate nitrogen, ammonia nitrogen, etc.] and " Through comparative analysis between each parameter of [soil moisture, pH, electrical conductivity, organic matter, nitrate nitrogen, ammonia nitrogen, etc.] Each parameter addition or subtraction information of "representative smart soil management information" for reaching each parameter may be generated as "first analysis information".

In addition, the crop condition analysis module 324 includes [temperature, humidity, wind speed, illuminance, etc. for each period (month, week, day, etc.)] and " Each parameter of the “representative smart soil management information”, each parameter of the “growth optimal model information” Each parameter addition or subtraction information of "representative smart soil management information" to arrive as a parameter may be generated as "second analysis information".

Then, the crop condition analysis module 324 operates the producer terminal 100 by controlling the transceiver 310 to transmit the first analysis information and the second analysis information to the producer terminal 100 through the network 200 . Agricultural producers can acquire data on which parts to supplement for climate information as well as farmland and soil information on the farmland they want to cultivate. In other words, when Chinese cabbage is planted in soil A, data on which crops are used and which fertilizers are used at what time in order to control the ratio of organic matter, nitrate nitrogen, and ammonia nitrogen can be obtained based on big data. If I know that when I plant Chinese cabbage, apples, etc., I only need to add a certain part, and not only do I not need an excessive amount of unnecessary fertilizer, but also select farmland throughout the country through the producer terminal (100) and add it, If you decide to plant lettuce in May by checking the changes, you can not only know how much and when to fertilize in May, but also know how many lettuce have been planted nationwide through multiple smart soil management information. Overproduction can be prevented.

The freight volume analysis module 325 generates average data through the accumulation of each period of "smart soil management information" for each unit area of the country, thereby creating a database 330 through the network 200 of the producer terminal 100. By granting access to the site based on member ID and password, it is possible not only to check the current status of land across the country, but also to know what crops can be cultivated at what time and how much yield can be raised with “smart soil management information” By providing accumulated data for each period of each period, it is possible to check the “transportation volume (agricultural product production) by number of cultivation by each cultivation medium”, which is linked to the meta data and the regional unit information. In addition, each agricultural product can also understand the price of agricultural products when cultivating a certain crop at any time.

The carbon-neutral analysis module 326 provides cultivation classification information (cabbage, apple, radish, pear, lettuce, etc.) Carbon reduction by cultivation medium information (seeds, seedlings, seedlings, etc.) By summing and storing in the database 330, it is possible to provide an effect that can help in the establishment of a national carbon-neutral policy.

The present invention can also be implemented as computer-readable codes on a computer-readable recording medium. The computer-readable recording medium includes all types of recording devices in which data readable by a computer system is stored.

Examples of computer-readable recording media include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage device, etc. also includes

In addition, the computer-readable recording medium is distributed in a computer system connected through a network, so that the computer-readable code can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily inferred by programmers in the technical field to which the present invention pertains.

As described above, preferred embodiments of the present invention have been disclosed in the present specification and drawings, and although specific terms are used, these are only used in a general sense to easily explain the technical content of the present invention and help the understanding of the present invention. , it is not intended to limit the scope of the present invention. It will be apparent to those of ordinary skill in the art to which the present invention pertains that other modifications based on the technical spirit of the present invention can be implemented in addition to the embodiments disclosed herein.

1: Smart soil management system 100: Producer terminal
100g: producer terminal group 200: network
300: smart soil management server 310: transceiver
320: control unit 321: soil information collection module
322: crop information collection module 323: climate information collection module
324: crop condition analysis module 325: trade volume analysis module
326: carbon neutral analysis module 330: database
400: big data server

Claims (5)

In the smart soil management system (1) comprising a producer terminal group (100g), a network (200), a smart soil management server (300) and a big data server (400) consisting of a plurality of producer terminals (100), smart soil The management server 300 includes a transceiver unit 310, a control unit 320 and a database 330, and the control unit 320 includes a soil information collection module 321, a crop condition information collection module 322, and climate information collection. It includes a module 323, a crop condition analysis module 324, a trade volume analysis module 325 and a carbon neutral analysis module 326,
Soil information collection module 321,
Controls the transceiver 310 to request the GPS location information and farmland soil information from the big data server 400 through the network 200 in a state where the GPS location information and farmland soil information are stored on the big data server 400 . Then, among the received GPS location information and farmland soil information, the GPS location information is divided by unit area of the country and collected on the database 330 as farmland soil information for each unit area, and the received farmland soil information is It includes soil moisture, pH, electrical conductivity, organic matter and nitrate nitrogen and ammonia nitrogen information.
The GPS location information and farmland soil information collected by the big data server 400 are collected from the soil information collection device and provided to the big data server 400 through the network 200, and the soil moisture, pH, Electrical conductivity, organic matter, nitrate nitrogen, and ammonia nitrogen are collected through the soil moisture sensor, organic matter sensor, pH sensor, nitrate nitrogen sensor, and ammonia nitrogen sensor provided in the soil information collection device,
The crop condition information collection module 322,
In a state where GPS location information and farmland soil information are stored on the big data server 400, the transceiver 310 is controlled to request the GPS location information and crop condition information from the big data server 400 through the network 200. Then, among the received GPS location information and harvesting information, GPS location information is divided by unit area of the country and collected on the database 330 as harvesting information for each divided unit area. including number information and cultivation medium information,
The GPS location information and crop status information collected by the big data server 400 are collected from the cultivation information collection device and provided to the big data server 400 through the network 200, and the cultivation information collection device is the producer terminal 100 or It is formed as a separate terminal device and compares the image pattern with image information obtained from the terminal device based on camera image recognition, a plurality of crop pattern information provided in the cultivation classification DB, and crop pattern information inclined at each preset angle. Extract cultivation classification information corresponding to crops from the image information, and a plurality of cultivation medium pattern information provided in the cultivation medium DB divided based on each extracted cultivation classification information, and information on cultivation medium pattern inclined at each preset angle. By comparing the image pattern with and extracting the cultivation medium from the image information, and calculating the number of each extracted cultivation medium, information on the number of cultivation is obtained,
The climate information collection module 323 is,
After controlling the transceiver 310 to request the meteorological area information and climate information from the big data server 400 through the network 200 in a state where the weather area information and the climate information are stored on the big data server 400 , each unit area through matching with unit areas of the country divided for use in the soil information collection module 321 and the crop condition information collection module 322 for meteorological area information among the received meteorological area information and climate information It is collected on the database 330 as climate information for each unit area divided by each, and the received climate information is each for each unit area of the country divided for use in the soil information collection module 321 and the crop condition information collection module 322. Includes information on temperature, humidity, wind speed, and illuminance during the period,
The climate information collection module 323 is,
For meteorological area information, when matching with unit areas of the country divided for use in the soil information collection module 321 and the crop condition information collection module 322, when the meteorological area information includes unit area information of the whole country Local information is used as unit area information, and when meteorological area information is included in unit area information of the whole country, the average value is calculated when generating climate information for each unit area while using all of the included meteorological area information as unit area information. use,
The farmland soil information, crop status information, and climate information for each unit area generated by the soil information collection module 321, the crop condition information collection module 322, and the climate information collection module 323 are “smart soil management” for each unit area. Information" is integrated and stored by the climate information collection module 323 in the database 330,
The crop condition analysis module 324 includes:
After a preset time corresponding to each smart soil management information elapses, the "cultivation medium The unit area for classifying smart soil management information by collecting "transport volume (agricultural product production)" compared to the number of cultivations by on/offline from farmers across the country including the producer terminal 100 as metadata on the database 330. save,
After access through the network 200 of the producer terminal 100, the transceiver unit to receive from the producer terminal 100 a request for cultivation analysis including GPS location information and crop condition information of the farmland that the producer wants to further cultivate. control 310;
Analyze the condition information for growth of agricultural products, which is the cultivation classification information to be cultivated, included in the request for cultivation analysis,
"Smart soil management information" divided into the same unit area as the current producer GPS location information is extracted, and farmland soil information and climate information included in the extracted smart soil management information are used to collect each divided climate information. The smart soil management information corresponding to the unit area that produced agricultural products, which is the cultivation classification information to be cultivated included in the request for cultivation analysis while having the most similar numerical value during the period, is extracted as “representative smart soil management information”,
By controlling the transmitter/receiver 310 to extract the "transport volume (agricultural product production)" of the "representative smart soil management information" and provide it to the producer terminal 100 through the network 200, the producer terminal ( 100) to predict the yield by
Each parameter of farmland soil information of “representative smart soil management information” and “growth optimal model information” for agricultural product cultivation, which is the cultivation classification information to be cultivated included in the cultivation analysis request for each parameter of climate information, is stored on a big data server Controls the transceiver 310 to receive through a request to (400),
Through comparative analysis between each parameter of growth optimal farmland soil information included in "growth optimal model information" and each parameter of farmland soil information in "representative smart soil management information", each parameter of "growth optimal model information" Each parameter of "representative smart soil management information" to reach is generated as "first analysis information",
"Representative for reaching each parameter of "growth optimal model information" through comparative analysis between each parameter of growth optimal climate information included in "growth optimal model information" and each parameter of climate information in "representative smart soil management information" Each parameter addition and subtraction information of "Smart Soil Management Information" is created as "Second Analysis Information",
Controls the transceiver 310 to transmit the first analysis information and the second analysis information to the producer terminal 100 through the network 200,
The traffic volume analysis module 325,
By generating average data through the accumulation of each period of "smart soil management information" for each unit area of the country, access to the database 330 through the network 200 of the producer terminal 100 is provided with a member ID and password By granting the basis, it not only makes it possible to grasp the current status of land across the country, but also uses “smart soil management information” and district-level information to determine how much yield can be raised when what crops are cultivated and at what time as metadata. By providing accumulated data for each period of each period, it is possible to check the "transport volume (agricultural product production) compared to the number of cultivation by cultivation medium" connected by
Carbon neutral analysis module 326,
Cultivation classification definition of crop status information for each unit area through "transport volume (agricultural product production) compared to number of cultivated units by cultivation medium" for each period and unit area for each period A smart soil management system, characterized in that the calculation value calculated by performing multiplication is stored in the database 330 by adding up all the cultivation classification information for each unit area. delete delete delete delete

Images