KR20130128120A - Domestic animal disease surveillance method - Google Patents

Abstract

Disclosed technology relates to a domestic animal infectious disease method, which includes: a step in which a first terminal senses infectious disease of domestic animals; a step in which a sensing result packet including at least one of a terminal ID of the first terminal sensing the infectious disease or a domestic animal ID of the domestic animal is transmitted to a server; a step in which the server receives the sensing result packet, and generates feedback according to the sensing result; a step in which the server determines at least one second terminal to receive the feedback, and transmits the feedback to the at least second terminal; and a step in which the second terminal outputs the received feedback through an output device. Therefore, the infectious disease is sensed and preparation plan is rapidly provided as the feedback. Also, in providing the feedback, the preparation plan and path are provided to the terminal transmitting the sensing result about the infectious disease through the feedback and also the feedback is provided to terminals located near to the terminal transmitting the sensing result. Thus, the situation of diffusion of damage of the infectious disease according as time goes on is prevented. [Reference numerals] (110) Sense infectious disease;(120) Transmit the sensing result;(130) Receive the sensing result and generate feedback;(140) Determine a terminal for receiving the feedback before transmission;(150) Output the feedback;(AA) Start;(BB) End

Description

Domestic Animal Disease Surveillance Method

The disclosed technique relates to a livestock epidemic surveillance method, and more particularly, but not limited to, a method for detecting an infectious disease that occurs in livestock and using feedback accordingly to prevent the spread of the epidemic and respond quickly.

Foot-and-mouth disease, mad cow disease, and bird flu are among the most infectious and lethal viruses in livestock. Conventional techniques for diagnosing such viruses determine whether the disease is caused by quarantine by analyzing the sampling of blood, feces, or parts of livestock suspected of developing an infectious disease. Once the results of the analysis are derived, countermeasures against the epidemic are taken. In other words, since it takes a long time in the process of diagnosing an infectious disease, the damage caused by the spread of the infectious disease occurs in proportion thereto. Conventional techniques related to diagnosis and prevention of infectious diseases include Korean Laid-Open Patent Publication No. 10-2011-0029760 (name of the invention: livestock epidemic management system).

Disclosed technology provides a method for monitoring livestock epidemic disease that can quickly determine whether an infectious disease occurs, and shorten the time required for prevention measures to provide measures for preventing and coping with the damage caused by the spread of the infectious disease.

A first aspect of the disclosed technology to achieve the above technical problem is the step of sensing (Sensing) the infectious disease of the livestock in the first terminal, the terminal ID of the first terminal or the livestock ID of the livestock of the first terminal detecting the infectious disease Transmitting the detection result packet including one or more to the server, receiving the detection result packet at the server, generating feedback according to the detection result, determining at least one second terminal to receive the feedback at the server, It provides a livestock epidemic monitoring method comprising the step of transmitting a feedback to at least one second terminal, and outputting the feedback received by the second terminal through an output device.

The second aspect of the disclosed technology to achieve the above technical problem is a sensing unit for detecting the infectious disease of the livestock (Sensing), an output unit for outputting a detection result for the infectious disease, the terminal ID or livestock of the terminal for detecting the detection result and the infectious disease Livestock epidemic monitoring terminal including a communication unit for transmitting a detection result packet including at least one of the livestock ID of the animal to the server, receiving a feedback on the detection result from the server, the alarm unit indicating a response or alert included in the received feedback To provide.

A third aspect of the disclosed technology to achieve the above technical problem is a detection result packet including at least one of the detection result of the infectious disease of the livestock from the first terminal and the terminal ID of the first terminal or the livestock ID of the domestic animal detected the infectious disease Receiving unit for receiving the; generating unit for generating feedback according to the detection result included in the detection result packet; determination unit for determining the second terminals using at least one of the terminal ID or the livestock ID, feedback to the second terminals It is to provide a livestock epidemic monitoring server including a sending unit for sending.

Embodiments of the disclosed technique may have effects that include the following advantages. It should be understood, however, that the scope of the disclosed technology is not to be construed as limited thereby, since the embodiments of the disclosed technology are not meant to include all such embodiments.

According to an embodiment of the disclosed technology, the livestock epidemic monitoring method is to spread the epidemic by providing a quick and efficient feedback when the epidemic occurs by transmitting the detection result of the infectious disease in the terminal to the server and at the same time to the output device of the terminal It is effective to prevent. In addition, the feedback is not provided only to the terminals transmitting the detection result to the server, but also provides feedback to other terminals located in the adjacent range from the terminal, thereby providing an effect of preventing the epidemic from occurring in the adjacent range.

1 is a flow chart for a livestock epidemic monitoring method according to an embodiment of the disclosed technology.
2 is a block diagram of a livestock epidemic monitoring terminal according to an embodiment of the disclosed technology.
3 is a block diagram of a livestock epidemic surveillance server according to one embodiment of the disclosed technology.
4 is a view connecting the livestock epidemic server and the terminal according to an embodiment of the disclosed technology.

The description of the disclosed technique is merely an example for structural or functional explanation and the scope of the disclosed technology should not be construed as being limited by the embodiments described in the text. That is, the embodiments are to be construed as being variously embodied and having various forms, so that the scope of the disclosed technology should be understood to include equivalents capable of realizing technical ideas.

Meanwhile, the meaning of the terms described in the present application should be understood as follows.

Terms such as “first” and “second” are used to distinguish one component from another component, and the scope of rights should not be limited by these terms. For example, the first component may be referred to as a second component, and similarly, the second component may also be referred to as a first component.

It is to be understood that when an element is referred to as being "connected" to another element, it may be directly connected to the other element, but there may be other elements in between. On the other hand, when an element is referred to as being "directly connected" to another element, it should be understood that there are no other elements in between. On the other hand, other expressions describing the relationship between the components, such as "between" and "immediately between" or "neighboring to" and "directly neighboring", should be interpreted as well.

Singular expressions should be understood to include plural expressions unless the context clearly indicates otherwise, and terms such as "include" or "have" refer to features, numbers, steps, operations, components, parts, or parts thereof described. It is to be understood that the combination is intended to be present, but not to exclude in advance the possibility of the presence or addition of one or more other features or numbers, steps, operations, components, parts or combinations thereof.

Each step may occur differently from the stated order unless the context clearly dictates the specific order. That is, each step may occur in the same order as described, may be performed substantially concurrently, or may be performed in reverse order.

All terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which the disclosed technology belongs, unless otherwise defined. Terms such as those defined in the commonly used dictionaries should be construed to be consistent with the meanings in the context of the related art and should not be construed as having ideal or overly formal meanings unless expressly defined in this application. .

1 is a flow chart for a livestock epidemic monitoring method according to an embodiment of the disclosed technology. Referring to FIG. 1, the method for monitoring livestock epidemic disease includes detecting a infectious disease of a livestock at a first terminal 110, a terminal ID of a first terminal detecting an infectious disease, and a livestock ID of a livestock. Transmitting the detection result packet including the above to the server 120, receiving the detection result packet, generating feedback according to the detection result 130, and determining at least one second terminal to receive the feedback, And transmitting the feedback to the at least one second terminal 140 and outputting the feedback through the output device 150. Hereinafter, the technical features and effects of each step will be described in detail.

Step 110 detects infectious diseases of livestock. For example, the infectious disease virus may be mad cow disease, foot-and-mouth disease or bird flu (bird flu) that can develop in cattle, pigs, and poultry, which are raised in barns. Meanwhile, in step 110, the first terminal uses a sensor or kit that detects an infectious disease. For example, the sensor may be a semiconductor chip that detects an infectious virus using an electrical signal. In another example, the kit may be to collect the feces or secretions of the livestock, or body parts of the livestock, and to determine whether the virus is present through the indicator or instrument. In the process of detecting an infectious disease as described above, the use of a sensor or a kit will be understood by those skilled in the art.

In step 120, the detection result of the infectious disease detected by the first terminal is transmitted to the server. Referring to an embodiment of the disclosed technology, the livestock epidemic monitoring method is in the form of a server-client model system in which a plurality of terminals and the server is connected to the network. Therefore, since the first terminal belongs to a plurality of terminals, the first terminal transmits each detection result of the infectious disease as a packet to the server. At this time, it transmits to the server which infectious disease was detected in which livestock in which region. That is, the first terminal transmits to the server a detection result packet including at least one of a terminal ID of the first terminal detecting the infectious disease or a livestock ID of the livestock in which the infectious disease is detected, together with the detection result of the infectious disease. The detection result is information on the type of epidemic and whether it has occurred. For example, the type of infectious disease is mad cow disease and whether or not it is developed can be expressed positively, and negative if not. The terminal ID is information on a region where the terminal is located or information identifying the terminal. For example, the terminal ID may indicate an area in which the terminal is located or represent an administrative area such as a city, a county, and a province. As another example, the terminal ID may be a unique code or serial number for identifying the terminal. The livestock ID is information for identifying each livestock individual. For example, the livestock ID may be an electronic chip inserted into the body of a cow or a pig, or may be a number tag attached to a body part of the livestock. In step 120, the detection result including the information is transmitted to the server in the form of a packet.

Meanwhile, the transmitted detection result (packet) is encrypted to prevent forgery and tampering in preparation for an external attack. In one embodiment of the disclosed technology, encryption is a method that makes it impossible to recognize except a server that is a legitimate recipient of a detection result to be transmitted. For example, the detection result transmitted from the first terminal to the server includes whether the virus causing the infectious disease is detected in the field corresponding to the message portion of the packet, the terminal ID of the terminal detecting the infectious disease, and the livestock ID of the livestock in which the infectious disease is found. In addition, the packet may be forged and tampered using an encryption method such as RSA or a hash function.

In step 130, a detection result packet is received and a feedback is generated according to the detection result. As described above, the detection result packet includes one or more of a detection result of an infectious disease and a terminal ID of a terminal detecting the infectious disease or a livestock ID of a livestock in which the infectious disease is found. In operation 130, a feedback is generated using the detection result among the information included in the detection result packet. In one embodiment of the disclosed technology, the feedback includes countermeasures or alerts against infectious diseases. The countermeasure provides an effect of allowing a user who uses the terminal to perform prompt defense work. For example, the countermeasure may be to generate a guide message or an alarm to isolate or prevent movement of livestock of the area, vehicle or barn where the terminal transmitting the detection result is located, if the detected infectious disease is foot-and-mouth disease. . As another example, the countermeasure may be a guide message indicating that there is no abnormality in the terminal that transmits the detection result when the infectious disease is not detected. Although not shown in the drawing, in step 130, in the step of generating an alarm according to the received detection result, the alarm may be notified to the administrator of the server as well as the second terminal. Therefore, the administrator of the server can determine whether the epidemic and the extent of the outbreak and quickly respond to it.

In step 140, the terminals for transmitting the feedback generated in step 130 are determined, and the feedback is transmitted to the determined terminals. For the detailed description of the disclosed technology, terminals determined to receive feedback are referred to as second terminals. Meanwhile, in the process of determining the terminals to which the feedback is to be transmitted, in step 140, area information for determining the second terminal is required. The area information is location information of the area where the terminals exist. For example, the local information may be a coordinate of a map or a GPS or an area such as a town, a town, and a town. In step 140, a part of terminals located in a predetermined region is determined as the second terminal based on the region information. In addition, it is well understood by those skilled in the art to include a database for storing local information to perform the above technical configuration. For example, step 140 may include a local information storage unit for storing local information.

Meanwhile, according to an embodiment of the disclosed technology, in addition to determining the second terminal through step 140, it is determined that the feedback is also transmitted to the terminals located in the reference range of the first terminal. The reference range is generally an administrative area such as a city, a county, a province, or a range included in a preset radius from the first terminal. For example, the reference range may be a range included in a radius of 10 km based on the first terminal. As another example, the adjoining range may be to use at least one of the commonly used administrative districts such as town, town, town, town, or city. As described above, when the terminal located in the predetermined range from the second terminal or the first terminal is determined as the second terminal to receive the feedback as described above, the server transmits the feedback to these terminals.

In step 150, the received feedback is output. Feedback is generated based on the detection result. Therefore, the feedback may include a response to the detected epidemic or an alarm on the detected epidemic. Countermeasures allow users to use the terminal to quickly control the epidemic. For example, the countermeasure may be a communicable disease prevention method or a guide message sent to the user of the terminal. Alarms are used to alert or warn of a hazard for an event or phenomenon, as is commonly used. That is, in one embodiment of the disclosed technology, an alert refers to a warning sound or a warning message according to the detection of an infectious disease. These countermeasures and alerts are included in the feedback. The feedback is output through the output device of the terminal. The output device is an image device or an audio device expressing feedback. For example, the output device may be a screen included in the terminal, and may display a message informing of a countermeasure against the infectious disease and an alarm through the screen. As another example, the output device is a speaker included in the terminal, and through the speaker may be a voice or alarm to respond to the infectious disease and alarm. As described above, one embodiment of the disclosed technology is in the form of a server-client. That is, according to an embodiment of the disclosed technology, technical features are performed according to an organic flow in each of the terminal and the server. Hereinafter, the terminal and the server will be described in detail with reference to FIGS. 2 and 3.

2 is a block diagram of a livestock epidemic monitoring terminal according to an embodiment of the disclosed technology. Referring to FIG. 2, the livestock epidemic monitoring terminal includes a sensing unit 210 for detecting a infectious disease of a livestock, an output unit 220 for outputting a detection result for the infectious disease, a detection result, and a terminal ID of the terminal for detecting the infectious disease. Or a communication unit 230 which transmits a detection result packet including at least one of the livestock IDs of the livestock to the server, and receives a feedback on the detection result from the server, and an alarm unit which outputs a countermeasure or alarm included in the received feedback ( 240).

The detector 210 detects an infectious disease. There are many ways to detect infectious diseases. For example, a method of detecting an infectious disease may be using a sensor that detects an infectious disease virus using an electrical signal. As another example, the reaction may be confirmed by applying a specimen such as animal waste or blood to a reagent or catalyst like a conventional pregnancy diagnosis device. The detection result is transmitted to the server and mapped to the data stored in the server. Technical features performed in the server will be described later with reference to FIG. 3.

The output unit 220 outputs the detection result for the previously detected infectious disease. The output unit 220 includes an image device and an audio device. The detection result is output through the imaging apparatus and the audio apparatus. For example, the image device of the output unit 220 may display the detection result on the screen. As another example, the sound device of the output unit 220 may be a speaker that indicates the detection result as sound or voice. On the other hand, the detection result is output as a screen or sound through the output unit 220 and is transmitted from the communication unit 230 to the server.

The communication unit 230 transmits the detection result of the infectious disease detected by the terminal to the server. In the transmission process, the communication unit 230 prevents forgery or damage of the detection result due to an external attack. Therefore, the detection results are sent to the server correctly. For example, in one embodiment of the disclosed technology, since the detection result has a form of a packet transmitted from the terminal to the server, the communication unit 230 may transmit the encrypted packet by an encryption algorithm such as a hash function or RSA.

The alarm unit 240 receives the feedback based on the detection result transmitted from the communication unit 230 from the server. And the feedback is output through the output unit 220. The received feedback is generated using at least one of a detection result included in the previously transmitted detection result packet and a terminal ID of the terminal detecting the infectious disease or a livestock ID of the livestock in which the infectious disease is detected. In other words, the feedback means to include a countermeasure or warning against an infectious disease based on this information. A process of generating feedback will be described in detail with reference to FIG. 3. The epidemic monitoring terminal undergoing this series of processes shows the exact result of whether the epidemic has occurred to the user and provides an effect of responding quickly through feedback received from a server connected to the terminal.

3 is a block diagram of a livestock epidemic surveillance server according to one embodiment of the disclosed technology. Referring to FIG. 3, the livestock epidemic monitoring server receives a detection result packet including a detection result for a infectious disease of a livestock and a detection result packet including at least one of a terminal ID of a first terminal or a livestock ID of a livestock from a first terminal, The generation unit 320 for generating feedback based on the detection result included in the detection result packet, and the determination unit 330 for determining the second terminal using at least one of the terminal ID or the livestock ID to receive the feedback. And a transmitter 340 for transmitting the feedback to the second terminal.

The receiver 310 receives a detection result packet transmitted from the terminal. As described above, the detection result packet includes at least one of a detection result and a terminal ID of the first terminal detecting the infectious disease or a livestock ID of the livestock in which the infectious disease is detected. Such a packet is encrypted and transmitted in order to prevent forgery or tampering caused by an external attack during transmission by the terminal. Therefore, it will be fully understood by those skilled in the art that the reception unit 310 should have a processing method for encryption and decryption set in advance with the terminal transmitting the detection result. For example, encryption and decryption may be using an RSA or hash algorithm. Meanwhile, the receiver 310 transmits the detection result packet including the information to the generation unit 320.

The generation unit 320 generates feedback using the detection result included in the detection result packet. Feedback may include countermeasures or alerts. In order to perform this process, the generation unit stores the detection result and the countermeasure mapped to the detection result. That is, the generation unit 320 includes a countermeasure storage unit 320a for storing the detection result and the countermeasure. For example, the countermeasure storage unit 320a may include a table having information on a sensing result and a countermeasure mapped to the sensing result, and may be a database using the sensing result stored in the table and the countermeasure mapped thereto. On the other hand, as described above, the countermeasure includes a message for allowing a user who uses the terminal to perform prompt defense work. Therefore, it provides an effect of preventing the spread of infectious diseases. In addition, the generation unit 320 includes an alarm along with a countermeasure against the generated feedback. The alarm serves to warn the user of the terminal of danger of an infectious disease through voice or alarm. To perform this role, the server transmits feedback to the terminal. Meanwhile, the generation unit 320 may notify the administrator of the server in the step of generating an alarm according to the received detection result. Therefore, the administrator of the server, when the alarm rings, determine whether the infectious disease and the extent of the occurrence, and prepare a countermeasure accordingly to provide an effect that can respond quickly to the epidemic like the user of the terminal.

The determiner 330 determines a terminal to receive the feedback generated by the generator 320. Referring to FIG. 1 described above, an embodiment of the disclosed technology defines, as a first terminal, a terminal that transmits a detection result for an infectious disease in a flow in which each step is performed. In other words, transmitting the feedback to the first terminal that has transmitted the detection result will be fully understood by those skilled in the art. However, the above-described process of performing a series of inaccurate information is provided to the user when some of the first terminals do not send or fail to send the detection result. Accordingly, an embodiment of the disclosed technology provides a feature for transmitting feedback not only to the first terminal but also to neighboring terminals. In other words, the determination unit 330 determines the second terminals using at least one of the terminal ID or the livestock ID included in the detection result packet transmitted from the first terminal, and transmits the feedback to the determined second terminals. As described above, in order to determine the second terminal, the determining unit 330 uses either the terminal ID of the first terminal or the livestock ID of the livestock in the detection result received from the receiving unit 310. The terminal ID includes location information of the terminal or unique information of the terminal. For example, the terminal ID may indicate an area such as a coordinate or a city, a county, and a province where the terminal is located. As another example, the terminal ID may be a unique code or serial number for identifying the terminal. The livestock ID also has information about the livestock individual. For example, the livestock ID may be an electronic chip inserted into the body of a cow or pig that has developed an infectious disease. The determination unit 330 stores local information mapped to the terminal ID or the livestock ID. That is, it includes a local information storage unit 330a for storing local information. Therefore, it is determined where the terminal transmitting the detection result is located via the terminal ID or the local information mapped to the livestock ID, or at which place the livestock is raised through the local information mapped to the livestock ID. In addition, in the process of determining as described above, it is well understood by those skilled in the art that it is possible to determine whether there is a terminal which does not transmit a detection result among the first terminals. Meanwhile, the determination unit 330 recognizes that the detected virus is a highly infectious disease in addition to determining the second terminal by using the terminal ID or the livestock ID, and detects to prevent the spread of the infectious disease. From the first terminal that transmitted the result packet, it is determined to send feedback to other terminals located in the reference range. The reference range is generally an administrative area such as a city, a county, a province, or is determined by setting a range in advance from the first terminal. For example, the reference range may be a range included in a radius of 10 km based on the first terminal. As another example, the reference range may be to use at least one of a predetermined administrative district such as a town, a town, a town, a town, a city, or a city generally used. Therefore, the provision of a close countermeasure against such an infectious disease shows a remarkable effect of preventing the spread of the infectious disease.

The transmitter 340 transmits feedback to the terminals determined above. The transmitter 340 of the server also transmits feedback in the form of a packet like the communicator 230 of the terminal. The packet is encrypted in order to prevent forgery or tampering caused by an external attack in the same way as the communication unit 230 transmits the packet. For example, the encryption method may be a hash function or a method using an RSA algorithm. Feedback sent from the transmitter to the terminal transmits the response to the infectious disease, including the alarm.

4 is a view showing a state in which the livestock epidemic monitoring terminal and the server according to an embodiment of the disclosed technology. Referring to FIG. 4, the livestock epidemic monitoring server 410 is connected to a plurality of terminals through a network. That is, the server and the plurality of terminals form one system. Prior to describing an embodiment of the disclosed technology with reference to FIG. 4, a terminal 420 is hereinafter referred to as a first terminal for convenience of description.

The terminal 420 detects an infectious disease. The terminal 420 includes the terminal ID of the terminal 420 together with the detection result of the infectious disease and transmits the terminal ID to the server 410. In this case, the terminal 420 may use the livestock ID of the livestock in which the infectious disease is detected instead of the terminal ID. The server 410 generates feedback based on the detection result included in the received detection result packet and determines a second terminal to receive the generated feedback. As a method of determining, as described above with reference to FIG. 1, the second terminal determines a terminal belonging to a reference range using local information stored in the local information storage unit 330a or based on the 420 terminal. For example, the server 410 may determine the terminal 420 and the terminal 430 as the second terminals using the region information stored in the region information storage unit 330a. As another example, the 410 server may determine terminals 420, 430, and 440 belonging to a reference range of the terminal 420 as second terminals. When the second terminal is determined in this manner, the 410 server transmits feedback to the determined second terminals. Feedback includes countermeasures and alerts as described above. Receiving this feedback, the second terminal outputs the response and the alarm included in the feedback through the output device included in each. Therefore, not only the user of the 420 terminal that transmits the detection result but also the user of the other terminal which is located in the vicinity of the terminal 420 receives the feedback, thereby providing an effect of quickly coping with and preventing the infectious disease.

Livestock epidemic monitoring method through an embodiment of the disclosed technology has been described with reference to the embodiment shown in the drawings for clarity, but this is merely illustrative, various modifications and equivalents from those skilled in the art It will be appreciated that other embodiments are possible. Therefore, the true technical protection scope of the disclosed technology should be defined by the appended claims.

110: infectious disease detection 120: transmission of detection results
130: reception and feedback generation 140: terminal determination and transmission
150: feedback output
210: detector 220: output unit
230: communication unit 240: alarm unit
310: receiver 320: generator
320a: Countermeasure generation unit 330: Decision unit
330a: local information storage unit 340: transmitter
410: plague monitoring server 420 to 460: plague monitoring terminal

Claims (19)

Sensing the infectious disease of the livestock at the first terminal (Sensing);
Transmitting a detection result packet including at least one of a detection result of the infectious disease and a terminal ID of the first terminal detecting the infectious disease or a livestock ID of the livestock to a server;
Receiving the detection result packet at the server and generating feedback according to the detection result;
Determining at least one second terminal to receive the feedback at the server, and transmitting the feedback to the at least one second terminal; And
Livestock epidemic monitoring method comprising the step of outputting the feedback received by the second terminal through an output device. The method of claim 1, wherein the transmitting of the detection result packet to a server comprises:
A livestock epidemic monitoring method for indicating the detection result through the output device, and preventing forgery or tampering with the detection result. The method of claim 1, wherein the output device,
Livestock epidemic monitoring method comprising the imaging device or audio device indicating the detection result or the feedback. The server according to claim 1,
And a countermeasure storage unit for storing the detection result and the countermeasures mapped thereto in advance, and generating the feedback to generate the feedback using the stored countermeasures. The server according to claim 1,
And an area information storage unit for storing the area information mapped to the terminal ID or the livestock ID in advance, and the determining of the at least one second terminal may include determining the second terminal using the stored area information. How to monitor infectious diseases. The method of claim 1, wherein the determining of the at least one second terminal comprises:
Livestock epidemic monitoring method for determining the terminal located in the reference range of the first terminal as the at least one second terminal. The method of claim 6, wherein the reference range is,
Livestock epidemic monitoring method comprising a range within a predetermined radius with respect to the administrative area, such as city, county or province or the first terminal is located. The method of claim 1, wherein the feedback is,
And an alarm according to the detection result, wherein the alarm is sounded through the output device. Sensing unit for detecting the infectious disease of the livestock (Sensing);
An output unit for outputting a detection result for the infectious disease;
A communication unit for transmitting a detection result packet including at least one of the detection result and the terminal ID of the terminal detecting the infectious disease or the livestock ID of the livestock to a server, and receiving a feedback on the detection result from the server; And
Livestock epidemic monitoring terminal comprising an alarm indicating the response or alert included in the received feedback. The method of claim 9, wherein the feedback is,
Livestock epidemic monitoring terminal comprising at least one of the countermeasures or alarm according to the detection result. The method of claim 9, wherein the alarm unit,
The feedback is displayed through the output device, the output unit livestock epidemic monitoring terminal comprising an image device or an audio device. The method of claim 9, wherein the output unit,
Livestock epidemic monitoring terminal for outputting the detection result or the feedback in video or audio. The communication device according to claim 9,
Livestock epidemic monitoring terminal for preventing forgery or tampering with the transmitted detection result. A receiving unit for receiving a detection result packet including at least one of a detection result of the infectious disease of the livestock and a terminal ID of the first terminal or the livestock ID of the domestic animal from the first terminal detecting the infectious disease;
A generation unit configured to generate feedback based on the detection result included in the detection result packet;
A determination unit to determine second terminals using at least one of the terminal ID and the livestock ID; And
Livestock epidemic monitoring server comprising a transmitter for transmitting the feedback to the second terminal. The method of claim 14, wherein the generation unit,
And a countermeasure storage unit for storing the detection result and the countermeasures mapped thereto in advance, and generating the feedback using the stored countermeasures. The method of claim 14, wherein the determining unit,
And an area information storage unit for storing area information mapped to the terminal ID or the livestock ID in advance, and determining the second terminals by using the stored area information. The method of claim 14, wherein the determining unit,
Livestock epidemic monitoring server for determining the terminals located in the reference range of the first terminal to the second terminal. The method of claim 17, wherein the reference range,
Livestock epidemic monitoring server comprising a range within a predetermined radius based on the administrative area, such as city, county or province or the first terminal is located. The method of claim 15, wherein the feedback,
And an alarm according to the countermeasure, wherein the alert comprises at least one of an alarm or a voice according to the countermeasure.

Images