KR102600416B1 - Smart Card-based Object History Management Method - Google Patents

Abstract

A smart card-based object history management method according to an embodiment includes the steps of receiving the state of an object from at least one sensor installed on the object, recognizing the user terminal by recognizing a smart card included in the user terminal, and It may include transmitting the corresponding object state to the user terminal and receiving a sensor adjustment signal for at least one sensor from the user terminal.

Description

Smart Card-based Object History Management Method}

The technical idea of the present disclosure relates to a method of managing object history, and more specifically, to a method of querying and managing object history according to the recognized smart card when recognizing a smart card.

Smart farms, a concept generally introduced to maximize the production and quality of agricultural products through precise environmental control, are attracting attention as a solution to the food security crisis facing humanity. Here, the smart farm mainly controls the temperature, humidity, amount of light, and carbon dioxide concentration inside the greenhouse. However, these smart farm environmental control systems can mainly be checked and managed only by actual managers. However, there may be many various devices and equipment needed to produce crops, such as various sensors, irrigation systems, and ion generators installed on the crops being grown. In relation to this, various facility engineers must also be able to check and manage the smart farm environmental control system.

However, rather than giving various equipment engineers the authority to check and control all equipment by accessing the smart farm environment control system, each equipment engineer should be given the authority to check and control only the equipment that they are responsible for.

The problem that the technical idea of the present disclosure seeks to solve is to provide a method for recognizing information stored in a smart card, limiting object history details that can be searched according to the user, and managing this.

A smart card-based object history management method according to an embodiment of the present disclosure includes the steps of receiving the state of an object from at least one sensor installed on the object, recognizing the user terminal by recognizing a smart card included in the user terminal, and the user It may include transmitting the object state corresponding to the terminal to the user terminal and receiving a sensor control signal for at least one sensor from the user terminal.

According to one embodiment, the step of receiving the state of the object includes receiving a sensing value measured from at least one sensor installed on the object at a preset time and calculating a calculation variable value using the received sensing value. It may include steps.

According to one embodiment, the step of recognizing the user terminal includes recognizing the smart card already included in the user terminal, and the step of recognizing the smart card includes user information included in the smart card. It may include the step of receiving.

According to one embodiment, the step of receiving the user information includes comparing the user information with existing user information that has been previously stored, and resetting the user classification included in the user information in response to the comparison result. may include.

According to one embodiment, transmitting the object state to the user terminal may include transmitting the sensing value and the calculated variable value corresponding to the set user classification to the user terminal.

According to one embodiment, the step of transmitting the object state to the user terminal may include blocking transmission of the sensing value and the calculated variable value that do not correspond to the set user classification to the user terminal. .

According to one embodiment, the step of receiving the sensor adjustment signal includes transmitting a warning alarm to the user terminal in response to a case where the sensing value and the calculated variable value deviate from a preset condition, and transmitting a warning alarm from the user terminal to the user terminal. It may include receiving a facility control signal for controlling at least one facility installed on the object, and adjusting the at least one facility installed on the object in response to the received facility control signal.

The smart card-based object history management method according to an embodiment of the present disclosure can be directly confirmed by receiving a sensing value installed on at least one object.

Additionally, because each facility has different access rights, each facility engineer can check the facility and manage the facility.

The effects that can be obtained from the exemplary embodiments of the present disclosure are not limited to the effects mentioned above, and other effects not mentioned are common knowledge in the technical field to which the exemplary embodiments of the present disclosure belong from the following description. It can be clearly derived and understood by those who have it. That is, unintended effects resulting from implementing the exemplary embodiments of the present disclosure may also be derived by those skilled in the art from the exemplary embodiments of the present disclosure.

Figure 1 is a block diagram showing the configuration of a server according to an embodiment of the present disclosure.
Figure 2 is a flowchart showing a smart card-based object history management method according to an embodiment of the present disclosure.
Figure 3 is a diagram illustrating a smart card-based object history management method according to an embodiment of the present disclosure.
FIG. 4 is a diagram illustrating an embodiment of providing the state of an object to a user by resetting the user classification according to an embodiment.

In the present invention, an object may be a smart farm. At this time, smart farms do not involve farmers who directly look at the crops every day and fertilize or water them, but rather include various sensors in the crops and check the current status/environment of the crops through the sensors, using wired or wireless devices. This means managing crops by controlling them.

In addition, there are no restrictions on the crops that can be grown in a smart farm, but for purposes of explaining the present invention, the crops grown in a smart farm here are limited to mushrooms. However, this is only a device for explaining the invention of the present application and does not limit the invention of the present application.

Specifically, in order to grow mushrooms, farmers must properly control temperature and humidity in the cultivation area 24 hours a day, day and night. However, because it is too inconvenient for farmers to do this every hour, temperature and humidity sensors can be installed in mushroom cultivation areas to detect this and control temperature and humidity. At this time, the sensor installed on the object of the present invention is not limited to a temperature sensor and a humidity sensor, and may be equipped with various sensors such as an illuminance sensor, a CO2 sensor that measures the concentration of CO2 in the air in the cultivation area, and a PH sensor. In addition, various facilities corresponding to sensors for controlling the sensed content may be installed. At this time, the installed equipment may be a dehumidifier, irrigation controller, air conditioning facility, etc.

Additionally, solar power generation, ion generators, plant growth sonic organs, etc. can be additionally installed on the object. Equipment/devices installed on objects are not limited to these if they are essential or helpful in growing crops.

Therefore, the object history in the present invention means that at least one sensor installed on the object senses the state/situation of the object, and when the sensed value is outside the preset range, the sensor installed on the object and the installed sensor This refers to all history of adjustments using corresponding devices/equipment. Additionally, access history to the devices/equipment and sensors described above may also be included.

In the present invention, the smart card may be USIM (Universal Subscriber Identity Module). However, the type of smart card of the present invention is not limited to USIM as long as it is included in the user terminal and can store user information and exchange information using any communication method inside/outside the user terminal.

Hereinafter, embodiments of the present disclosure will be described in detail with reference to the attached drawings.

Figure 1 is a block diagram showing the configuration of a server according to an embodiment of the present disclosure.

Referring to FIG. 1, the server 10 may be composed of a server or electronic device that performs operations on input information, and includes an ATMP 110, RAM (Random Access memory) 120, storage 130, and UDAP. (140) and TMP (150).

The server 10 can manage the issuance of applications and applets for services based on the smart card-based object history management method, which is an embodiment of the present invention, to the user terminal.

ATMP (Application & Thing Management Part: 110) can control the overall operation of the server 10. The ATMP 110 may include one processor core (Single Core) or a Central Processing Unit (CPU) including a plurality of processor cores (Multi-Core). Server 10 may include one or more ATMPs 110.

ATMP 110 may process or execute programs, data, or instructions stored in storage 130. For example, the ATMP 110 executes programs stored in the storage 130 to calculate calculation variable values, which will be described later, using values sensed through sensors installed in the object, or to use devices/facilities installed in the object. You can.

When the sensing value sensed from an object is outside a preset range, the ATMP 110 generates a signal to the object to adjust it and transmits the signal through the UDAP 140, which will be described later.

When the ATMP 110 recognizes a smart card through the UDAP 140, which will be described later, the ATMP 110 can compare/confirm the user information included in the smart card with existing user information already stored in the storage 130, which will be described later.

The ATMP (110) directly manages the object history management system to be downloaded from the server (10) to a smart card or user terminal. In addition, if the entire object history management system needs to be upgraded, it can be upgraded according to pre-set results. Also, if there is an upgrade in the smart card or user terminal, it is triggered and related tasks are performed when connected.

RAM 120 may temporarily store programs, data, or instructions. For example, programs and/or data stored in the storage 130 may be temporarily stored in the RAM 120 according to the control or booting code of the processor 110. For example, the RAM 120 includes Dynamic RAM (DRAM), Static RAM (SRAM), and Synchronous DRAM (SDRAM).

The storage 130 is a storage location for storing data, and can store an operating system (OS), various programs, and various data. The storage 130 includes read only memory (ROM), flash memory, phase-change RAM (PRAM), magnetic RAM (MRAM), resistive RAM (RRAM), and ferroelectric RAM (FRAM). In an embodiment, the storage 130 may be implemented as a hard disk drive (HDD), solid state drive (SSD), or the like.

Information stored in the storage 130 may include sensor values measured by various sensors for managing a smart farm, calculation variable values calculated using the measured sensor values, and user information to be described later.

UDAP 140 may transmit and/or receive data from the server 10. For example, UDAP 140 can transmit and receive data using various communication methods. For example, UDAP 140 can perform communication by, for example, 3G, LTE, Wi-Fi, Bluetooth, BLE (Bluetooth Low Energy), Zigbee, NFC (Near Field Communication), ultrasonic communication method, etc. , can include wired communication, wireless communication, short-distance communication, and long-distance communication, and can recognize smart cards, which will be described later.

TMP (Thing Management Part: 150) manages the versions and related information profiles of various programs for managing object history by syncing them with the user terminal and converting them into a database.

Accordingly, the server 10 of the present disclosure can perform operations using the above configurations, temporarily store data or commands, or transmit and/or receive data with user terminals and objects.

Hereinafter, an embodiment of the present invention will be described in detail based on Figures 2 and 3. FIG. 2 is a flowchart illustrating a smart card-based object history management method according to an embodiment of the present disclosure, and FIG. 3 is a diagram illustrating a smart card-based object history management method according to an embodiment of the present disclosure.

Before explaining, in the present invention, an application may refer to an application that is directly used by a user, that is, a user using a user terminal, when the smart card-based object history management method, which is an embodiment of the present invention, is implemented.

Hereinafter, this specification may be described with reference to FIG. 1.

The user terminal 30 may include a smart card 31, User Thing Management Part (UTMP) 310, User Menu Management Part (UMMP) 320, and User Application & Thing Management Part (UATMP) 330.

The user terminal 30 can configure a user interface according to the profile, store and manage all object history in the object history management system, and perform tasks preset according to the profile, such as version. At this time, the entire object history management system can also be upgraded, and related tasks can be performed through a combination of the functions of each component.

The UTMP 310 can manage the object history management profile in a memory (ex. EEPROM, FRAM, PRAM, or MRAN). Additionally, the UTMP 310 may be composed of an application profile (not shown) and an object profile (not shown). Here, the application profile (not shown) includes the name, hidden status, version, size, menu order, etc. of the application that manages the object history, and the object profile (not shown) includes the entire name, sensor name, and sensor of the object 20. It can include value, access scope, etc.

UMMP (not shown) can perform functions such as menu composition and order of the application of the object management history system, which is an embodiment of the present invention. At this time, UMMP (not shown) configures the menu according to the profile information of the UTMP (150) and the device status of the user terminal 30, and transmits the results through the interface with the user to the UATMP (150) to perform the task. . Additionally, MUI (Menu User Interface (not shown)) may include images and configuration logic for UI configuration.

The UATMP 320 is a part of VM applications and objects. The objects and applications are located in the application area like WAM of a terminal platform such as WIPI and play the role of running the application according to the request of MUN (not shown). However, the user terminal 30 of the present disclosure is not limited to using the terminal platform of WIPI, and can also run an application by transmitting and receiving data through a system bus.

In addition, it may further include SAA (Service Application Agent: not shown), TPA (Terminal Platform Agent: not shown), DLM (Download Manager: not shown), and DIM (Download Information Manager: not shown). At this time, SAA (not shown) is a WIPI VM application program area, and TPA (not shown) may be an area where objects are located. In addition, DLM (not shown) is a network interface module that performs a download function and is used as a network interface module for the server 10. It performs error recovery functions that occur during the download process while interfacing with the ATMP 110. In addition, DIM (not shown) and SMS DLM (not shown) manage status information, trigger information, etc. required when performing the download function.

The user terminal 30 may additionally include TCMP (Terminal Command Management Part: 330). At this time, the TCMP (330) is an area that processes commands that must be performed while interfacing with the smart card (31). It opens a channel through a security authentication function such as Mutual Auth and transmits the APDU received from UMMP (not shown) or UATMP (320). Execute the same command. Additionally, the TCMP 330 may include a Terminal Command Agent (TCA) (not shown), and the server 10 may further include a Card Access Manager (CAM) and a Card Manager (not shown). there is.

TCA (not shown) is responsible for stringing together APDUs and command series delivered in batches into logical units and transmitting the results. In addition, CAM (not shown) is a physical interface area for interfacing with the smart card 31 included in the user terminal 30. It interfaces with the smart card according to the ISO7816 standard, and in the future, it will be used to interface with the smart card 31 included in the user terminal 30. Interface functions can also be added. In addition, CM (not shown) recognizes the smart card 31 and drives UMMP (not shown) and UATMP (320) according to the results.

In the step of receiving the state of the object (S110), the server 10 may receive the state of the object 20 from a sensor installed on the object 20.

More specifically, in the step of receiving the object state (S110), the server 10 may receive the state of the object from a sensor installed on the object 20 at preset times. At this time, the sensing value included in the object state This may include the sensed illuminance value, temperature value, humidity value, CO2 concentration value in the air, and nutrient solution pH concentration value during nutrient solution cultivation. Additionally, the calculated variable value can be calculated using the received sensing value. The calculated variable value may include an increase/decrease displacement value calculated using the previously described sensing values, a displacement value according to time change, and a predicted displacement value using the calculated displacement value.

Additionally, additional variable values may be generated in addition to the previously described sensing values and calculated variable values.

Additional variable values include , , X variables, Z variables, and U variables may be included. is the predicted amount of sample increase/decrease displacement measured by the biomass sensor, is a value including aXi (environmental variable close to the crop), bZi (environmental variable within the smart farm), and cUi (environmental variable outside the smart farm), and the p), the Z variable is a value including outdoor temperature and humidity, solar radiation, rainfall, wind speed (s), and wind volume (d), and the U variable is a control coefficient and a variable value to correct inter-regional differences.

The server 10 can obtain values corresponding to the X variable from sensors in the smart farm and predict crop yield based on the obtained values. Illustratively, the server 10 may further include a crop yield prediction model learned by artificial intelligence, and the prediction model may include , , you can calculate the predicted value of crop yield by entering the X variable, Z variable, and U variable.

Additionally, the server 10 may predict crop yield rate through a preset mathematical model. As an example, the crop yield rate may be predicted by summing the values multiplied by the weights for each additional variable value. At this time, the server 10 may multiply each additional variable value by a different weight according to the user classification set as user information. The sum of the weights multiplied by each additional variable value may be 1, and the ratio between the weights may be set according to the user classification. As an example, user classification may be classified according to the number of information provided to the user, and the X variable corresponding to the information obtained from the smart farm may be multiplied with more weight in proportion to the number of information provided. In other words, the weight multiplied by the X variable may be proportional to the number of information provided to the user terminal.

Accordingly, the server 10 of the present disclosure can manage to predict crop yield by placing a higher weight on the X variable as more information is provided as the X variable.

In the step S120 of recognizing the user terminal 30, the server 10 may recognize the user terminal. In more detail, the server 10 may recognize the user terminal 30 by recognizing the smart card 31 included in the user terminal 30.

The UDAP 140 can recognize the user terminal 30 using wired/wireless, NFC, etc. When the smart card 31 included in the user terminal 30 is recognized, the server 10 can receive user information included in the smart card 31. The user information may include personal information of the user terminal owner and information on the user terminal 30. The personal information of the user terminal owner may include information such as the owner's name, date of birth, telecommunication company, and personal mobile phone number. Information on the user terminal 30 may include unique information such as the serial number of the terminal, and, if the user terminal is a mobile phone, may include IMEI (International Mobile Equipment Identity). Additionally, user information may include user classification, which will be described later.

Existing user information may include the user's name, mobile phone number, and access range information. To explain the access range information as an example, the access range of the smart farm owner who operates the mushroom smart farm is All, which allows access to all devices and all sensors, and the access range of the repairman who repairs temperature sensors and thermostats is All. The range may be TS (Temperature Sensor) - TC (Temperature Controller).

FIG. 4 is a diagram illustrating an embodiment of providing the state of an object to a user by resetting the user classification according to an embodiment.

Referring to FIG. 4, when the server 10 receives user information included in the smart card 31, the server 10 exchanges the user's name and mobile phone number stored in the existing user information with the information included in the user information. You can compare and reset the user classification included in the user information in response to the comparison results.

For example, the information included in the user information is ‘Wonhyeong Kim, 1972.07.05, 010-1111-2222, user classification (undetermined)’, and the existing user information is ‘Wonhyeong Kim, 1972.07.05, 010-1111-2222. Assume that information called 'HS-HC' is stored. If the server 10 compares the above two pieces of information and determines that they are the same, the user information changes from 'Wonhyeong Kim, 1972.07.05, 010-1111-2222, user classification (undetermined)' to 'Wonhyeong Kim, 1972.07.05, 010-1111-2222. , can be reset to 'HS-HC'. This means that the user using this user's terminal is entitled to access HS-HC (Humidity Sensor - Humidity Control) among various sensors and devices/equipments installed on objects.

In the step (S130) of transmitting the object state to the user terminal 30, the server 10 may transmit the sensing value, calculated variable value, and additional variable value sensed by the user terminal to the user terminal.

The server 10 transmits the object state to the user terminal 30, but does not transmit all sensing values, all calculation variable values, and all additional variable values. The server 10 can transmit only specific values according to the previously set user classification to the user terminal, and values other than the transmitted values can be blocked from being transmitted to the user terminal 30.

For example, to the user terminal 30 whose user classification is TS-TC (temperature sensor-temperature controller), the server 10 provides a temperature sensing value sensed by a temperature sensor corresponding to the user classification and a displacement related to the temperature sensing value. Information containing values (calculated variable values) and additional variable values can be transmitted. At this time, information such as CO2 sensing value and solar power generation power amount unrelated to TS-TC may be blocked from being transmitted to the user terminal 30.

Additionally, the server 10 may receive additional access requests from the user for sensors and facilities/devices to which the user wishes to access. In response to such a request, the server 10 may check the previously set user classification and accept or block the access request. If the access request information received from the server 10 matches the user classification, the sensing value, calculated variable value, and additional variable value corresponding to the access request may be transmitted to the user terminal 30 in response, and the user classification Access to equipment/equipment corresponding to may also be permitted. However, if the received access request information and the user classification do not match, the server 10 may block the sensing value, calculated variable value, and additional variable value from being transmitted to the user terminal in response to the mismatch, and related Access to devices/equipment may also be blocked.

For example, when an access request for a temperature sensor-temperature controller (TS-TC) is received from the user terminal 30 whose user classification is TS-TC, the server 10 confirms that the user classification and the access request are the same. , allows all access to TS-TC. At this time, all permitted access means that all variable values (sensing values, calculated variable values, additional variable values) related to TS-TC can be checked and devices/equipment for TS-TC can be operated.

In the step of receiving a sensor control signal (S140), the server 10 may receive a sensor control signal from the user terminal 30. In addition, in the step of receiving the sensor control signal (S140), the server 10 sends a warning alarm to the user terminal 30 if the sensing value and calculated variable value previously transmitted to the user terminal 30 deviate from preset conditions. Can be sent.

To explain with a specific example, the temperature for growing mushrooms should be maintained between 12 and 20 degrees. Therefore, the preset condition can be specified as 12 to 20 degrees. At this time, if the sensed temperature is outside this range of 12 to 20 degrees, the server 10 sends a warning alarm to the user terminal 30 that the temperature is out of range, so that the mushroom grower knows this and adjusts the temperature. It can be done so that you can do it.

Additionally, in the step of receiving a sensor control signal (S140), the server 10 may receive a equipment control signal for controlling equipment/devices installed on the object 20 from the user terminal 30.

Even if the user receives or does not receive the above-described warning alarm, the server 10 can receive control signals regarding facilities/devices installed on the object 20 from the user. Specifically, when a user receives a warning alarm about temperature, rather than directly operating the temperature controller, the user may transmit a facility control signal to operate the temperature controller at the desired temperature and receive this signal from the server. Additionally, even if the user wants to adjust the temperature when he or she does not receive a warning alarm, he or she can transmit a facility signal to cause the temperature controller to operate, rather than operating the temperature controller directly.

Additionally, in the step of receiving the sensor control signal (S140), the server 10 may adjust the equipment/devices installed on the object 20 in response to the previously received equipment control signal. Specifically, if the facility control signal received from the user is a signal for increasing the temperature by 2 degrees, the server 10 uses the temperature controller to increase the temperature by 2 degrees. However, if the equipment control signal received from the user does not correspond to the user classification, the server may not respond to the equipment control signal received.

More specifically, if the server receives a facility control signal to increase humidity by 5% for HS-HC from a user whose type is TS-TC, the server adjusts the sensor and facility/device received by the user type. Since it does not correspond to the type, it may not respond to the previously received message 'Increase humidity by 5%'.

As described above, the server 10 can receive a facility control signal even if the user does not receive a warning alarm. However, if the user classification does not correspond to the facility control signal, the server 10 does not correspond to the facility control signal.

As above, exemplary embodiments have been disclosed in the drawings and specification. Although embodiments have been described in this specification using specific terms, this is only used for the purpose of explaining the technical idea of the present disclosure and is not used to limit the meaning or scope of the present disclosure as set forth in the claims. . Therefore, those skilled in the art will understand that various modifications and other equivalent embodiments are possible therefrom. Therefore, the true technical protection scope of the present disclosure should be determined by the technical spirit of the attached patent claims.

Claims (7)

In a method of managing object history by a server providing a service based on a smart card-based object history management method,
Receiving the state of an object from at least one sensor installed on the object;
Recognizing the user terminal by recognizing a smart card included in the user terminal;
transmitting the object state corresponding to the user terminal to the user terminal; and
Receiving a sensor control signal for at least one sensor from the user terminal;
Including,
The step of receiving the object state is,
Receiving a sensing value measured by at least one sensor installed on the object at a preset time;
Predicted sample increase/decrease displacement measured by biomass sensor and obtain crop proximity environmental variables, environmental variables within the smart farm, and environmental variables outside the smart farm. The values including temperature and humidity, carbon dioxide concentration, pH, EC, nutrient solution supply amount, and wind volume (p) are obtained as Obtaining as a variable, and obtaining the variable value as a U variable to correct inter-regional deviations with a control coefficient; and
remind , remind , calculating a predicted value of crop yield by multiplying different weights according to the number of information provided to the user for the X variable, the Z variable, and the U variable.
A smart card-based object history management method comprising: delete According to claim 1,
The step of recognizing the user terminal is,
Recognizing the smart card already included in the user terminal,
The step of recognizing the smart card is,
Receiving user information included in the smart card;
A smart card-based object history management method comprising: According to clause 3,
The step of receiving the user information is,
Comparing the user information with existing user information that has been previously stored; and
A step of resetting the user classification included in the user information in response to the comparison result.
A smart card-based object history management method comprising: According to paragraph 4,
The step of transmitting the object state to the user terminal is,
Transmitting the sensing value and the calculated variable value corresponding to the set user classification to the user terminal.
Smart card-based object history management method comprising: According to paragraph 4,
The step of transmitting the object state to the user terminal is,
Blocking transmission of the sensing value and the calculated variable value that do not correspond to the set user classification to the user terminal.
Smart card-based object history management method comprising: According to claim 1,
The step of receiving the sensor control signal is,
Transmitting a warning alarm to the user terminal in response to a case where the sensing value and the calculated variable value deviate from preset conditions;
Receiving a facility control signal for controlling at least one facility installed on the object from the user terminal; and
Adjusting the at least one facility installed on the object in response to the received facility adjustment signal
Smart card-based object history management method comprising: