KR102353127B1 - Smart farm black box, smart farm data managing method, and smart farm system - Google Patents

Abstract

According to an embodiment of the present invention, when the smart farm controller for controlling the smart farm internal environment is in the manual control mode, a relay line receiver for receiving manual control information from the smart farm controller; a network communication unit configured to receive automatic control information from the smart farm control unit when the smart farm control unit is in an automatic control mode; and a database for receiving the manual control information from the relay line receiving unit and receiving the automatic control information from the network communication unit, wherein the database receives and stores the manual control information from the relay line receiving unit information storage unit; and an automatic control information storage unit configured to receive and store the automatic control information from the network communication unit.

Description

Smart farm black box, smart farm data management method, and smart farm system

The present invention relates to a smart farm black box, a data management method using the smart farm black box, and a smart farm system.

Started to develop Korean smart farm technology as a technology-intensive next-generation agricultural system that can overcome the small scale of Korean farmland and have external competitiveness (Rural Development Administration, 2014). Currently, Korean smart farms are equipped with the technology to sense the greenhouse environment (temperature, humidity, CO2, etc.) is being disseminated. As of 2017, these smart farms were installed in 1,710 farms.

As a result of the implementation of the smart farm dissemination project, the problem of lack of reliability due to the breakdown and malfunction of smart farm ICT equipment, which is a difficulty in the field, has been pointed out as an obstacle to the spread of smart farms. In addition, the possibility of disputes between farmers and businesses is increasing, such as damage to farms and disputes due to problems such as poor system and inexperienced operation of farmers.

As such, field effects are increasing due to the spread of smart farms, but new difficulties and R&D field demands are occurring in the field. Therefore, there is a need to develop an operation record management system for smart farm equipment as a field failure technology to accurately identify the cause of a smart farm system failure.

An object of the present invention is to provide a smart farm black box and a smart farm data management method capable of managing the operation records of equipment in order to accurately identify the cause of the failure of the smart farm system.

Another object of the present invention is to provide a smart farm system that includes a smart farm black box and is connected to a network to perform smart farm control and monitoring through a user terminal.

According to an embodiment of the present invention, when the smart farm controller for controlling the smart farm internal environment is in the manual control mode, a relay line receiver for receiving manual control information from the smart farm controller; a network communication unit configured to receive automatic control information from the smart farm control unit when the smart farm control unit is in an automatic control mode; and a database for receiving the manual control information from the relay line receiving unit and receiving the automatic control information from the network communication unit, wherein the database receives and stores the manual control information from the relay line receiving unit information storage unit; and an automatic control information storage unit configured to receive and store the automatic control information from the network communication unit.

According to an embodiment of the present invention, there is provided a smart farm black box in which the network communication unit receives smart farm sensor information from a smart farm sensor unit that detects an internal environment of the smart farm.

According to an embodiment of the present invention, there is provided a smart farm black box further comprising a sensor information storage unit for storing the smart farm sensor information.

According to an embodiment of the present invention, the automatic control information and the manual control information received from the relay line receiving unit and the network communication unit are encrypted and transmitted to the manual control information storage unit and the automatic control information storage unit, respectively. A smart farm black box is provided, further comprising a module.

According to an embodiment of the present invention, there is provided a smart farm black box in which the manual control storage unit and the automatic control storage unit classify and store the smart farm control information according to a preset event table.

According to an embodiment of the present invention, by extracting smart farm control information from a smart farm control unit for controlling a smart farm driving unit that controls the state of the internal space of a smart farm house that provides an internal space for growing crops, transmitting to the smart farm black box; extracting smart farm sensor information from a smart farm sensor unit provided inside the smart farm house to detect the state of the internal space and transmitting the smart farm sensor information to the smart farm black box; and storing the smart farm control information and the smart farm sensor information in the smart farm black box, wherein the smart farm control information and the smart farm sensor information are classified and stored according to a preset event table. A data management method is provided.

According to an embodiment of the present invention, the event table includes a smart farm control information table for classifying the smart farm control information; and a smart farm sensor information table for classifying the smart farm sensor information, wherein the smart farm control information table and the smart farm sensor information table have different data extraction parameters.

According to an embodiment of the present invention, the smart farm control information includes a switch operation signal generated when manually controlling the smart farm driving unit; and a magnet operation signal generated when automatically controlling the smart farm driving unit, the smart farm data management method is provided.

According to an embodiment of the present invention, the smart farm control information and the smart farm sensor information are encrypted by at least one encryption key table and stored in the smart farm black box, and the encrypted smart farm control information and the smart farm control information A method for managing smart farm data in which farm sensor information is decoded and output by at least one decryption key table is provided.

According to an embodiment of the present invention, the encryption key table and the decryption key table form a pair corresponding to each other, and the encryption key table and the decryption key table corresponding to each other are generated from the same variable authentication key, smart farm data management A method is provided.

According to an embodiment of the present invention, a smart farm house that provides an internal space for growing crops; a smart farm driving unit provided on the smart farm house to control the state of the internal space; a smart farm control unit for controlling the smart farm driving unit; a smart farm sensor unit provided inside the smart farm house to detect a state of the internal space; and a smart farm black box receiving smart farm control information from the smart farm control unit and receiving smart farm sensor information from the smart farm sensor unit, wherein the smart farm black box and the smart farm control unit are configured from the smart farm control unit. Connected by an extended smart farm control relay line, the smart farm control information includes manual control information transmitted to the smart farm black box by the smart farm control relay line, and the smart farm black box is connected by a network. A smart farm system connected to a cloud server and a user terminal is provided.

According to an embodiment of the present invention, it is possible to manage the operation record of the equipment in order to accurately determine the cause of the failure of the smart farm system.

In addition, according to an embodiment of the present invention, smart farm system operation record data management is easy and security is high.

In addition, according to an embodiment of the present invention, smart farm control and monitoring can be performed remotely through a user terminal.

1 is a block diagram illustrating a smart farm black box according to an embodiment of the present invention.
2 is a block diagram illustrating a relationship between a smart farm black box and peripheral devices according to an embodiment of the present invention.
3A and 3B show a data classification method of a smart farm black box and a classified data output screen according to an embodiment of the present invention.
4A and 4B show a data classification method of a smart farm black box and a classified data output screen according to an embodiment of the present invention.
5 is a block diagram illustrating a smart farm black box according to an embodiment of the present invention.
6 and 7 are block diagrams illustrating a smart farm system according to an embodiment of the present invention.
8 shows a smart farm system according to an embodiment of the present invention.
9 is a block diagram illustrating a method of operating a smart farm system according to an embodiment of the present invention.

Since the present invention can have various changes and can have various forms, specific embodiments are illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to the specific disclosed form, it should be understood to include all modifications, equivalents and substitutes included in the spirit and scope of the present invention.

In describing each figure, like reference numerals have been used for like elements. In the accompanying drawings, the dimensions of the structures are enlarged than the actual size for clarity of the present invention. Terms such as first, second, etc. may be used to describe various elements, but the elements should not be limited by the terms. The above terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component. The singular expression includes the plural expression unless the context clearly dictates otherwise.

In the present application, terms such as "comprise" or "have" are intended to designate that a feature, number, step, operation, component, part, or a combination thereof described in the specification exists, but one or more other features It is to be understood that it does not preclude the possibility of the presence or addition of numbers, steps, operations, components, parts, or combinations thereof. Also, when a part of a layer, film, region, plate, etc. is said to be “on” another part, it includes not only the case where the other part is “directly on” but also the case where there is another part in between. In addition, in the present specification, when a portion such as a layer, film, region, or plate is formed on another portion, the formed direction is not limited only to the upper direction, and includes those formed in the side or lower direction. . Conversely, when a part of a layer, film, region, plate, etc. is said to be "under" another part, this includes not only cases where it is "directly under" another part, but also cases where there is another part in between.

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

According to an embodiment of the present invention, data generated from smart farm equipment can be efficiently collected and managed using a smart farm black box, and through this, it is possible to easily determine whether the smart farm equipment is abnormal.

1 is a block diagram illustrating a smart farm black box according to an embodiment of the present invention.

The smart farm black box 10 is connected to the smart farm control unit that controls the smart farm equipment and stores smart farm control information generated when the smart farm equipment is controlled.

The smart farm black box 10 may be connected to the smart farm control unit by wire and/or wirelessly, and accordingly, the smart farm control information may be transmitted to the smart farm black box 10 by wire and/or wirelessly.

The smart farm black box 10 may include various sub-modules to receive, classify, and store smart farm control information.

Referring to FIG. 1 , the smart farm black box 10 includes a data receiving unit 100 and a database 200 .

The data receiver 100 connects the smart farm black box 10 and an external device by wire and/or wirelessly, and performs a function of receiving information transmitted from the external device. In this case, the external device may be a smart farm control unit for controlling the environment within the smart farm or a smart farm sensor unit for sensing the environment within the smart farm.

The data received by the data receiving unit 100 includes smart farm control information. The smart farm control information means information that the smart farm control unit receives from the smart farm control unit for controlling the smart farm internal environment. The smart farm control unit may transmit various control signals to the smart farm equipment in order to control the smart farm internal environment. The control signal transmitted from the smart farm control unit is transmitted to the data receiving unit 100 in the form of smart farm control information. can be

The data receiving unit 100 includes a relay line receiving unit 110 and a network communication unit 120 to receive smart farm control information.

The relay line receiver 110 receives manual control information from the smart farm controller when the smart farm controller is in the manual control mode. Manual control information is a kind of smart farm control information, and refers to a control signal generated from the smart farm control unit after the user operates the smart farm control unit in the manual control mode to directly control the smart farm equipment.

The relay line receiving unit 110 may be connected to the smart farm control unit through a relay line, and manual control information may be transmitted to the relay line receiving unit 110 through the connected relay line. Details on this will be described later.

The network communication unit 120 receives automatic control information from the smart farm control unit when the smart farm control unit is in the automatic control mode. The automatic control information is a kind of smart farm control information, and refers to a control signal generated to control the smart farm internal environment according to an algorithm preset in the smart farm control unit regardless of a user's operation. The automatic control information may be generated according to smart farm internal environment information input to the smart farm control unit, that is, smart farm sensor information.

Data received by the network communication unit 120 and the relay line receiving unit 110 may be transmitted to the database 200 .

The database 200 stores data received from the relay line receiving unit 110 and the network communication unit 120 . To this end, the database 200 includes a manual control information storage unit 210 for storing the manual control information received from the relay line receiving unit 110 and an automatic control information for storing the automatic control information received from the network communication unit 120 . and a control information storage unit 220 . The manual control information storage unit 210 and the automatic control information storage unit 220 may be virtual drives divided into partitions in one physical storage. Alternatively, the manual control information storage unit 210 and the automatic control information storage unit 220 may be physically separate storages.

The database 200 may classify and store the data received from the data receiver 100 according to preset criteria. For example, the preset data extraction parameters stored in the database 200 may be an operation time, a control name, a control mode, an operation, an access method, an opening rate, and the like.

As smart farm control information is classified and stored in the database 200 , desired information among smart farm control information can be easily retrieved and checked according to user needs.

The database 200 may include a drive and/or removable storage mounted on the smart farm black box 10 . Accordingly, the information stored in the database 200 may be exported to the outside through the removable storage.

According to an embodiment of the present invention, the smart farm black box 10 receives smart farm control information and classifies and stores the received information according to a preset data extraction parameter, thereby efficiently storing data generated in the smart farm equipment. can be collected and managed.

In the above, the internal configuration of the smart farm black box was examined. Hereinafter, the relationship between the smart farm black box and external devices will be examined in more detail.

2 is a block diagram illustrating a relationship between a smart farm black box and peripheral devices according to an embodiment of the present invention.

Referring to FIG. 2 , the relationship between the smart farm black box 10 , the smart farm control unit 20 , the smart farm driving unit 30 , and the smart farm sensor unit 40 can be checked.

The smart farm control unit 20 transmits a control signal to control the smart farm internal environment. The smart farm control unit 20 may include a main module 21 , a manual control unit 22 , and a magnet 23 to perform the above-described functions.

The main module 21 may be a computing device that receives smart farm sensor information from the smart farm sensor unit 40 that detects the smart farm internal environment and performs an operation required for control. For example, after receiving the smart farm sensor information, the main module 21 may generate a control signal to perform an operation for lowering the corresponding numerical value to the normal standard when a specific value is greater than or equal to a normal standard.

The manual control unit 22 may generate a corresponding control signal according to the manipulation of the user in the manual control mode. The manual control unit 22 is specifically activated by receiving mode information that the current smart farm control unit 20 is in the manual control mode from the main module 21, and the manual control unit 22 is operated by a user only in an activated state can generate a control signal according to the When the manual control unit 22 is in an inactive state, even if the user USER operates the smart farm control unit 20 , the manual control unit 22 may not generate a control signal.

The control signal generated by the manual control unit 22 may be the manual control information described above. The manual control information may be transmitted to the smart farm driving unit 30 and the smart farm black box 10 through the relay line RL. Details of the relationship between the relay line RL and the smart farm black box 10 will be described later.

The magnet 23 receives the control signal generated by the main module 21 and transmits the control signal to the smart farm driving unit 30 accordingly. The magnet 23 may specifically transmit automatic control information for turning on/off the operation of the smart farm driving unit 30 to the smart farm driving unit 30 . The automatic control information transmitted from the magnet 23 may also be transmitted to the smart farm black box 10 .

The smart farm driving unit 30 receives a control signal from the manual control unit 22 and/or the magnet 23 and performs an operation for controlling the smart farm internal environment. The smart farm driving unit 30 may include, for example, a length opening/closing device, a ceiling opening/closing device, a thermal cover, a light shield, a ventilation fan, a flow fan, an exhaust fan, a light beam, a heater, and the like. The measurement opening/closing device is a ventilation window installed on the side of the smart farm facility, and may be a device for opening and closing the left and right sides of the smart farm facility. The ceiling opener may be a window installed on the roof or ceiling of a smart farm facility for the purpose of photosynthesis and ventilation of crops. The thermal insulation cover is a cover for conserving heat inside the smart farm facility, and can be operated horizontally or vertically. The shading screen can be operated horizontally as a screen to prevent damage to crops by sunlight. Ventilators are installed at the front and rear of the smart farm facility to receive outside wind and exhaust the inside air to the outside to control the temperature and humidity inside the smart farm facility. The floating fan is a fan that circulates air in the smart farm facility, and can be controlled so that the temperature and humidity inside the smart farm facility are uniform. The exhaust fan is a fan that exhausts the air inside the smart farm facility and can be used to control temperature and humidity. The auxiliary light may be an artificial light source that additionally supplies light when the amount of insolation is insufficient. The heater may be an air conditioning device used for temperature control inside the smart farm facility.

The smart farm sensor unit 40 detects and measures the environment inside the smart farm. The smart farm internal environment detected by the smart farm sensor unit 40 may be transmitted to the smart farm control unit 20 or the smart farm black box 10 in the form of smart farm sensor information.

The smart farm sensor unit 40 may include various types of sensors to detect the internal environmental state of the smart farm. For example, the smart farm sensor unit 40 may include a temperature sensor, a humidity sensor, a solar radiation sensor, a wind direction sensor, a wind speed sensor, and a rainfall sensor. The temperature sensor can provide information for temperature control, ventilation, and air circulation-related control by sensing the temperature inside and outside the smart farm facility. The humidity sensor can provide control information related to ventilation, dehumidification, and air circulation by measuring the amount of water vapor contained in the air inside and outside the smart farm facility. The solar sensor can measure solar energy and provide information related to temperature and irrigation control in the smart farm facility. The wind direction sensor can measure the amount of wind and provide temperature and ventilation window-related control information inside the smart farm facility. The wind speed sensor may measure the speed of the wind and provide control information for ventilation windows (skyscrapers, side windows, etc.). The rainfall sensor can detect rain and provide control information necessary for opening and closing ventilation windows of smart farm facilities.

The smart farm black box 10 includes a relay line receiving unit 110 and a network communication unit 120 as described above.

The relay line receiving unit 110 may be connected to a relay line RL extending from the smart farm control unit 20 to receive manual control information. The relay line RL connects the manual control unit 22 and the smart farm driving unit 30 , and transmits manual control information corresponding to the manipulation of the user USER to the smart farm driving unit 30 . In this case, a part of the relay line RL connecting the manual control unit 22 and the smart farm driving unit 30 may be connected to the relay line receiving unit 110 . Accordingly, the manual control information may be transmitted to the smart farm driving unit 30 along the relay line RL and simultaneously transmitted to the relay line receiving unit 110 . Therefore, even when the user directly manipulates the smart farm control unit 20 in the manual control mode, control information can be recorded in the smart farm black box 10, and data integrity is increased.

The network communication unit 120 receives automatic control information transmitted from the magnet 23 of the smart farm control unit 20 to the smart farm driving unit 30 . The network communication unit 120 may receive automatic control information transmitted from the magnet 23 by wire or wirelessly. For example, the smart farm control unit 20 and the network communication unit 120 may communicate wirelessly through a network hub connected to the Internet.

The network communication unit 120 may also receive smart farm sensor information from the smart farm sensor unit 40 . The smart farm sensor information received by the network communication unit 120 means environment information collected from the smart farm sensor unit provided inside and outside the smart farm. The smart farm sensor information may include sensing time, wind direction, wind speed, temperature, humidity, amount of sunlight, rainfall amount, carbon dioxide amount, ground temperature, humidity information, and the like.

The network communication unit 120 and the smart farm sensor unit 40 may be connected by wire or wirelessly. For example, the above-described network hub may also connect the smart farm sensor unit 40 and the network communication unit 120 . In this case, various sensors included in the smart farm sensor unit 40 may be Internet of Things (IoT) devices capable of Internet communication.

The data storage unit 200 may further include a sensor information storage unit 230 to store smart farm sensor information transmitted from the network communication unit 120 . The sensor information storage unit 230 may be a virtual drive divided into partitions in one physical storage. Alternatively, the sensor information storage unit 230 may be a separate storage physically distinct from the manual control information storage unit 210 and the automatic control information storage unit 220 .

The data storage unit 200 stores the data received from the network communication unit 120 in the automatic control information storage unit 220 or the sensor information storage unit 230 to determine whether to store the data received prior to data storage. can be classified. Specifically, the data storage unit 200 stores the data in the automatic control information storage unit 220 when the data received from the network communication unit 120 is automatic control information, and when the received data is smart farm sensor information, data may be stored in the sensor information storage unit 230 . The data storage unit 200 may perform the above-described classification operation by checking a data tag of data received from the network communication unit 120 . To this end, the network communication unit 120 may attach an appropriate data tag according to the type of data received before transmitting the data to the data storage unit 200 .

The security module 300 may perform a function of encrypting or decrypting data in the smart farm black box 10 . For example, the security module 300 may encrypt the smart farm control information received by the data receiver 100 and transmit it to the database 200 . Details of encryption and decryption through the security module 300 will be described later.

According to an embodiment of the present invention, the relay line receiving unit 110 and the network communication unit 120 may receive manual control information and automatic control information, respectively. Accordingly, when the user directly manipulates the smart farm control unit 20 or when the smart farm control unit 20 generates a control signal by a preset algorithm, the control information may be stored in the smart farm black box 10 . Therefore, according to the present invention, since control information can be stored in the smart farm black box 10 without omission, data integrity is excellent.

In the above, data communication between the smart farm black box and external devices has been reviewed. Hereinafter, we will look at how data is processed inside the smart farm black box.

3A and 3B show a data classification method of a smart farm black box and a classified data output screen according to an embodiment of the present invention.

Referring to FIG. 3A , the smart farm control information (CD) and the classified smart farm control information (CD-S) may be checked.

The smart farm control information CD may be manual control information or automatic control information. The smart farm control information (CD) may include various types of information. For example, the smart farm control information CD may include first control information DT-1, second control information DT-2, and third control information DT-3. The first control information DT-1, the second control information DT-2, and the third control information DT-3 may include any one of an operation time, a control name, a control mode, an operation, a connection method, and an opening rate. may be, and may be different types of information.

An information tag for data classification is attached to each of the first control information DT-1, the second control information DT-2, and the third control information DT-3 included in the smart farm control information CD. can be For example, each of the first control information DT-1, the second control information DT-2, and the third control information DT-3 includes a first control information tag TG-C1 and a second control An information tag TG-C2, and a third control information tag TG-C3 may be attached.

Prior to storing the smart farm control information (CD) in the data storage unit, the smart farm control information (CD) may be classified according to an attached information tag. Specifically, the data storage unit may classify data by checking whether the information tag and the data extraction parameter correspond. For example, the data storage unit may include first to third data extraction parameters PR-1, PR-2, and PR-3. Each of the first data extraction parameters to the third data extraction parameters PR-1, PR-2, PR-3 is a first control information tag (TG-C1), a second control information tag (TG-C2), and a second 3 Corresponds to the control information tag (TG-C3).

The first data extraction parameters to the third data extraction parameters PR-1, PR-2, PR-3 and the first control information tag TG-C1, the second control information tag TG-C2, and the third By matching the control information tag TG-C3, the first control information DT-1, the second control information DT-2, and the third control information DT-3 are classified and the smart classified accordingly Farm control information (CD-S) may be generated.

At least one of the first data extraction parameters to the third data extraction parameters PR-1, PR-2, and PR-3 may be a control mode information extraction parameter. Accordingly, even if the manual control information and the automatic control information are received at the same time, the information can be classified and stored according to the control mode.

The user can easily call the smart farm control information connected thereto by loading specific data extraction parameters as needed.

3B exemplarily shows the output form of the classified smart farm control information (CD-S) stored in the database.

Referring to FIG. 3B , the classified smart farm control information (CD-S) is classified according to parameters such as operation time, control name, control mode, operation, connection method, and opening rate.

Accordingly, the user can easily check information included in the received control information at any point in time, and can easily check whether or not an abnormal operation has been performed by arranging data according to a desired parameter.

4A and 4B show a data classification method of a smart farm black box and a classified data output screen according to an embodiment of the present invention.

According to FIG. 4A , the smart farm sensor information SD and the classified smart farm sensor information SD-S may be checked.

The smart farm sensor information SD may also include a plurality of different types of sensor information and a plurality of different types of information tags, similar to the smart farm control information CD. For example, the smart farm sensor information SD may include first sensor information DT-4, second sensor information DT-5, and third sensor information DT-6, each of which includes A first sensor information tag TG-S1 , a second sensor information tag TG-S2 , and a third sensor information tag TG-S3 may be attached thereto. At this time, the first sensor information tag (TG-S1), the second sensor information tag (TG-S2), and the third sensor information tag (TG-S3) are the above-described first control information tag (TG-C1), the second It is different from the second control information tag (TG-C2) and the third control information tag (TG-C3).

Prior to storing the smart farm sensor information SD in the data storage unit, the smart farm control information SD may be classified according to an attached information tag. Specifically, the data storage unit may classify data by checking whether the information tag and the data extraction parameter correspond. For example, the data storage unit may include fourth data extraction parameters to sixth data extraction parameters PR-4, PR-5, and PR-6. Each of the fourth data extraction parameters to the sixth data extraction parameters PR-4, PR-5, PR-6 is a first sensor information tag (TG-S1), a second sensor information tag (TG-S2), and a second 3 Corresponds to the sensor information tag (TG-S3). In this case, the fourth data extraction parameters to the sixth data extraction parameters PR-4, PR-5, and PR-6 are the above-described first data extraction parameters to the third data extraction parameters PR-1, PR-2, and PR. -3) is different.

A fourth data extraction parameter to a sixth data extraction parameter (PR-4, PR-5, PR-6), a first sensor information tag (TG-S1), a second sensor information tag (TG-S2), and a third By matching the sensor information tag TG-S3, the first sensor information DT-4, the second sensor information DT-5, and the third sensor information DT-6 are classified, and the smart classified accordingly Palm sensor information SD-S may be generated.

The user can easily call the smart farm sensor information connected thereto by loading specific data extraction parameters as needed.

4B exemplarily shows the output form of the classified smart farm sensor information (SD-S) stored in the database.

Referring to FIG. 4B , the classified smart farm sensor information SD-S is classified according to sensor location, operation time, wind direction, wind speed, temperature, humidity, solar radiation, and rainfall.

Accordingly, the user can easily check the information included in the smart farm sensor information received at any point in time, and by arranging the data according to a desired parameter, it is possible to easily check whether an abnormal state has appeared in the smart farm.

In the above, a method of classifying smart farm control information and smart farm sensor information in the data storage unit has been reviewed. Smart farm control information and smart farm sensor information may be encrypted in the security module prior to classification and storage. Hereinafter, a method of encrypting and decrypting smart farm control information and smart farm sensor information in the security module will be described.

5 is a block diagram illustrating a smart farm black box according to an embodiment of the present invention.

According to FIG. 5 , the smart farm control information and/or smart farm sensor information received by the data receiver 100 is transmitted to the security module 300 . The data receiving unit 100 includes a relay line receiving unit and a network communication unit. In this embodiment, for convenience of explanation, the term data receiving unit 100 is used as a concept to collectively refer to a relay line receiving unit and a network communication unit.

The security module 300 may encrypt the received smart farm control information and/or smart farm sensor information using the encryption key table. In this case, the security module 300 may include at least one encryption key table, and accordingly, data received at different times or different types of data may be encrypted by different encryption key tables. For example, the security module 300 may include a first encryption key table (EN1) and a second encryption key table (EN2), the first encryption key table (EN1) is the data received at the first point in time It is used for encryption, and the second encryption key table EN2 may be used to encrypt data received at a second time point different from the first time point. The first encryption key table EN1 and the second encryption key table EN2 may be a one-time variable encryption key table generated from a variable authentication key.

The security module 300 may encrypt data through the modified AES128 encryption scheme.

Since encrypted information is stored in the database 200, the security of smart farm control information and/or smart farm sensor information may be increased. Accordingly, even if a third party extracts smart farm control information and/or smart farm sensor information from the database 200 without permission using a removable storage, it may be difficult to interpret the encrypted information.

The encrypted smart farm control information and/or smart farm sensor information stored in the database 200 may be transmitted to the output device 80 according to a user's request. The output device 80 may be of various types, such as a mobile device and a PC. Prior to transmitting the smart farm control information and/or smart farm sensor information to the output device 80 , the encrypted smart farm control information and/or smart farm sensor information may be decrypted in the security module 300 . To this end, the security module 300 may include at least one decryption key table. For example, the security module 300 may include a first decryption key table DE1 and a second decryption key table DE2, which are respectively a first encryption key table EN1 and a second encryption key table ( It may correspond to EN2). Accordingly, the security module 300 may decrypt the smart farm control information and/or the smart farm sensor information by using the encryption key table used to encrypt data and the corresponding decryption key table, and transmit it to the output device 80 .

The encryption key table and the decryption key table corresponding to each other may be generated based on the same variable type authentication key.

The above-described encryption and decryption method by the security module 300 is exemplary, and various encryption and decryption methods may be used. For example, the security module 300 may encrypt and decrypt smart farm control information and/or smart farm sensor information using a blockchain verified by a plurality of smart farm users.

In the above, we have looked at the smart farm black box in detail. Hereinafter, a smart farm system including a smart farm black box will be examined.

6 and 7 are block diagrams illustrating a smart farm system according to an embodiment of the present invention.

6 and 7, the smart farm system 1000 includes a smart farm black box 10, a smart farm control unit 20, a smart farm driving unit 30, a smart farm sensor unit 40, and a smart farm house ( 50).

The smart farm black box 10 , the smart farm control unit 20 , the smart farm driving unit 30 , and the smart farm sensor unit 40 are the same as described above.

The smart farm house 50 provides an internal space for growing crops. The smart farm house 50 may be provided, for example, in the form of a greenhouse.

A smart farm driving unit 30 is provided on the smart farm house 50 . The smart farm driving unit 30 may include various devices as described above, and the state of the space inside the smart farm house 50 may be controlled according to the movement of these devices.

A smart farm sensor unit 40 may be provided inside the smart farm house 50 . The smart farm sensor unit 40 may detect the state of the inner space of the smart farm house 50 , and may allow the user to take an appropriate action automatically or directly according to this.

The smart farm control unit 20 may be provided outside the smart farm house 50 . In addition, the smart farm black box 10 may be provided adjacent to the smart farm control unit 20 .

The smart farm system 1000 according to an embodiment of the present invention includes the smart farm black box 10, so that the smart farm control information and the smart farm generated by the smart farm control unit 20 and the smart farm sensor unit 40 Sensor information can be recorded.

In the above, a smart farm system including one smart farm house and one smart farm black box was examined. However, the smart farm system may include a plurality of smart farm houses and smart farm black boxes, and the plurality of smart farm black boxes may be connected by a network. Hereinafter, a smart farm system including a plurality of smart farm houses will be described.

8 shows a smart farm system according to an embodiment of the present invention.

Referring to FIG. 8 , the smart farm system includes a plurality of smart farm houses, and each smart farm house includes a smart farm black box. For example, a first smart farm black box 10a, a second smart farm black box 10b, and a third smart farm black box 10c may be provided.

The first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c may be connected by a network. Specifically, the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c may be network-connected to the cloud server CS. There is no limitation on a network connection method between the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c and the cloud server CS. For example, Code Division Multiple Access (CDMA) method, GSM method, GPRS method, EDGE method, WCDMA method, UMTS method, TD-SCDMA method, HSDPA method, HSUPA method, HSPA+ method, LTE method, Various network connection methods used in the art, such as the EV-DO method and the WIBRO method, may be used.

Data stored in the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c may be transmitted to the cloud server CS according to a preset period. . Accordingly, information stored in the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c may be backed up through the cloud server CS. In addition, the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c remove the backed-up information from the cloud server CS, thereby providing data in the physical storage. storage can be reduced.

The first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c may receive data from the cloud server CS as necessary. For example, data removed from the first smart farm black box 10a, the second smart farm black box 10b, and the third smart farm black box 10c is transferred from the cloud server CS according to the user's request. You can receive data in the form of download.

The cloud server (CS) may be provided in various forms, such as Infrastructure as Service (IaaS), Platform as a Service (PaaS), and Software as a Service (SaaS).

The cloud server (CS) may be connected to multiple smart farms at the same time. The cloud server CS provides a unique ID for each connected smart farm, so that multiple smart farms can be connected to the cloud server CS at the same time.

The cloud server CS may be connected to the cloud database DB. Accordingly, data stored in the cloud server CS is stored in the cloud database DB, and the cloud server CS may load and transmit appropriate data from the cloud database DB according to a user request.

The cloud server CS may be connected to the user terminal MD. The user terminal MD may access the cloud server CS to control the smart farm or receive necessary information related to the smart farm.

The user terminal MD may be a device having an output function and a communication function, such as a mobile phone, a PDA, a PC, a laptop, and a tablet PC, in order to perform the above-described functions.

The user may access the cloud server CS through the user terminal MD. In this case, the user may request permission to access the cloud server CS by transmitting user access information assigned to him/her to the cloud server CS. The cloud server CS may check whether the stored user access information and the user access information received from the user terminal MD match, and may permit or block the user access.

The cloud server CS may connect a specific smart farm among a plurality of smart farms with the user terminal MD by using the user access information transmitted from the user terminal MD. The user terminal MD may transmit a control signal to the connected smart farm through the cloud server CS or receive information related to the connected smart farm through the cloud server CS. Accordingly, smart farm control and monitoring is possible even when the user is away from the smart farm.

According to an embodiment of the present invention, as the smart farm and the user terminal (MD) are connected through the cloud server (CS), data management and smart farm management are very easy.

In the above, the connection type between the smart farm and the user terminal by the cloud server (CS) has been examined. When a plurality of smart farms and the cloud server are connected, the cloud server may perform an authentication procedure to prevent the user terminal from controlling the unrelated smart farm. Hereinafter, we will look at these authentication procedures.

9 is a block diagram illustrating a method of operating a smart farm system according to an embodiment of the present invention.

According to FIG. 9 , first, the cloud server receives data from the smart farm black box (S100). The data reception method may be performed as a wired/wireless communication method as described above. The data received by the cloud server may be smart farm control data and/or smart farm sensor data.

Next, the cloud server may tag the received data with a black box ID. The black box ID may mean identification information assigned to the smart farm black box. The black box ID may be provided in various forms, such as a Mac address of the smart farm black box.

Next, data tagged with the black box ID may be encrypted (S300). In this case, encryption may be performed within a cloud server or an external database connected to the cloud server. The encryption method may be various, such as a public key method or a block chain method. When data is encrypted using the block chain method, a plurality of smart farm black boxes connected to the cloud server can participate in block chain authentication. The encrypted data may be stored in the cloud server or in an external database connected to the cloud server.

Next, when there is an access request from the user terminal, the cloud server checks the user access information received from the user terminal (S400). The user access information may be provided in the form of an ID and password, and the cloud server may check whether the stored ID and password match the ID and password received from the user terminal. If the user information received from the user terminal does not match the user information stored in the cloud server, the cloud server may reject the user's access.

Next, the cloud server may check whether the user access information and the black box ID match. Specifically, the user access information may include information on a specific smart farm black box ID, and the cloud server may check whether there is a black box ID that matches the smart farm black box ID included in the user access information.

Among the smart farm black boxes connected to the cloud server, if there is a smart farm black box having a black box ID that matches the black box ID included in the user access information, the cloud server connects the user terminal and the corresponding smart farm black box.

At this time, for example, data tagged with a black box ID may be loaded from a cloud server or an external database (S600).

If there is no smart farm black box with a black box ID that matches the black box ID included in the user access information among the smart farm black boxes connected to the cloud server, the cloud server checks the user access information again and connects the user to the user terminal again. You can request information.

Accordingly, it is possible to prevent a third party from accessing the unrelated smart farm black box and stealing information or controlling the smart farm without permission.

After the data tagged with the black box ID is loaded from the cloud server or an external database, the data tagged with the black box ID may be decrypted (S700). The user terminal receives the decrypted data, and accordingly, the user terminal may check the data through the user terminal.

According to an embodiment of the present invention, even when a plurality of smart farms are connected to the cloud server, the cloud server goes through an authentication procedure and only authorized users connect to the smart farm, so that the security of the smart farm can be improved.

Although the above has been described with reference to a preferred embodiment of the present invention, those skilled in the art or those having ordinary skill in the art will not depart from the spirit and scope of the present invention described in the claims to be described later. It will be understood that various modifications and variations of the present invention can be made without departing from the scope of the present invention.

Accordingly, the technical scope of the present invention should not be limited to the content described in the detailed description of the specification, but should be defined by the claims.

10: smart farm black box 100: data receiver
110: relay line receiving unit 120: network communication unit
200: data storage unit 210: manual control information storage unit
220: automatic control information storage unit

Claims (10)

a relay line receiver configured to receive manual control information from the smart farm controller when the smart farm controller for controlling the smart farm internal environment is in a manual control mode;
a network communication unit configured to receive automatic control information from the smart farm control unit when the smart farm control unit is in an automatic control mode;
a database for receiving the manual control information from the relay line receiving unit and receiving the automatic control information from the network communication unit; and
A security module for encrypting and decrypting the automatic control information and the manual control information,
the database is
a manual control information storage unit for receiving and storing the manual control information from the relay line receiving unit; and
and an automatic control information storage unit for receiving and storing the automatic control information from the network communication unit,
The relay line receiving unit associates a first control information tag with the manual control information, and transmits the manual control information to the security module,
The network communication unit associates a second control information tag with the automatic control information, and transmits the automatic control information to the security module;
The security module generates encryption control information by encrypting the automatic control information and the manual control information based on a plurality of encryption key tables defined differently depending on the reception time of each of the automatic control information and the manual control information, and the transfer encryption control information to the database;
The database classifies and stores the manual control information and the automatic control information according to a preset data extraction parameter when receiving the manual control information and the automatic control information,
The preset data extraction parameter is set differently for each of the first control information tag and the second control information tag,
The database stores the encryption control information when receiving the encryption control information, and when receiving a request from an output device, decrypts the encryption control information based on a plurality of decryption key tables to generate decryption control information, and the decryption pass control information to the output device;
The plurality of decryption key tables are defined differently according to each reception time of the automatic control information and the manual control information. The method of claim 1,
The network communication unit receives the smart farm sensor information from the smart farm sensor unit that detects the environment inside the smart farm, a smart farm black box. 3. The method of claim 2,
The database further includes a sensor information storage unit for storing the smart farm sensor information. delete delete receive smart farm control information from a smart farm control unit for controlling a smart farm internal environment, wherein the smart farm control information includes automatic control information and manual control information;
receiving smart farm sensor information from a smart farm sensor unit that detects an internal environment of the smart farm;
causing a first control information tag to correspond to the manual control information, and a second control information tag to correspond to the automatic control information;
Encrypting the automatic control information and the manual control information based on a plurality of encryption key tables to generate encryption control information; When receiving the manual control information and the automatic control information, the manual control information and the automatic control information Classify and store according to preset data extraction parameters,
wherein the preset data extraction parameter is set differently for each of the first control information tag and the second control information tag; and
When receiving the encryption control information, the encryption control information is stored, and when receiving a request from an output device, the encryption control information is decrypted based on a plurality of decryption key tables to generate decryption control information, and the decryption control information is pass to the output device,
The smart farm control information and the smart farm sensor information are classified and stored according to a preset event table,
The plurality of encryption key tables are defined differently depending on the reception time of each of the automatic control information and the manual control information,
The plurality of decryption key tables are differently defined according to each reception time of the automatic control information and the manual control information. delete 7. The method of claim 6,
the manual control information is input by a user, and
The automatic control information is generated according to the smart farm sensor information, smart farm data management method. delete a smart farm house that provides an interior space for growing crops;
a smart farm driving unit provided on the smart farm house to control the state of the internal space;
a smart farm control unit for controlling the smart farm driving unit;
a smart farm sensor unit provided inside the smart farm house to detect a state of the internal space;
and a smart farm black box for receiving smart farm control information from the smart farm control unit and receiving smart farm sensor information from the smart farm sensor unit,
The smart farm black box and the smart farm control unit are connected by a smart farm control relay line extending from the smart farm control unit,
The smart farm control information includes manual control information transmitted to the smart farm black box by the smart farm control relay line and automatic control information transmitted through network communication by the smart farm control unit,
The smart farm black box,
causing a first control information tag to correspond to the manual control information, and a second control information tag to correspond to the automatic control information;
Generate encryption control information by encrypting the automatic control information and the manual control information based on a plurality of encryption key tables defined differently depending on the reception time of each of the automatic control information and the manual control information,
When receiving the manual control information and the automatic control information, the manual control information and the automatic control information are classified and stored according to a preset data extraction parameter,
The preset data extraction parameter is set differently for each of the first control information tag and the second control information tag,
When the encryption control information is received, the encryption control information is stored, and when requested from an output device, the encryption control information is decrypted based on a plurality of decryption key tables to generate decryption control information, and the decryption control information is used in the pass to the output device,
The plurality of decryption key tables are defined differently according to each reception time of the automatic control information and the manual control information,
The smart farm black box is connected to a cloud server and a user terminal by a network, a smart farm system.

Images