KR101837719B1 - Mosquito Control System - Google Patents

Abstract

The present invention relates to a mosquito control system with improved efficiency, According to the present invention, the mosquito control system comprises: a mosquito meter measuring the number of mosquitoes; a storage database (DB) for receiving and storing the number of mosquitoes measured from the mosquito meter; a calculation module for calculating an average value of the measured number of mosquitoes and storing the calculated average value in the storage DB; a mosquito generation grade application target selection module for comparing and selecting the average number of mosquitoes in the storage DB and the average number of mosquitoes measured in real time; a mosquito generation grade setting module for setting a mosquito generation grade; a mosquito generation grade application module for selecting grades for each mosquito monitoring area; a mosquito control management server having a mosquito appearing map production module; and a portable terminal for receiving a mosquito appearing map from the mosquito control management server and outputting the same in an identifiable manner.

Description

Mosquito Control System with Improved Efficiency {

The present invention relates to a mosquito control system, more particularly, to a mosquito control system that real-time measures the amount of mosquitoes generated in each region and prioritizes mosquito control areas, thereby improving the efficiency of performing centralized control To an improved mosquito control system.

Generally, mosquitoes are grown in a humid summer marsh in a wetland such as a water shed, and the population of the mosquitoes is multiplied by vomiting of animals or humans for about 20 days. It is accompanied by infectious pathogens in the process of proliferation through such bloodsucking.

For example, domestic indigenous mosquito-borne infectious diseases include Japanese encephalitis and malaria, and infectious mosquito-borne infectious diseases include dengue fever, West Nile fever, and chicavirus infection.

Japanese encephalitis and malaria, which are indigenous mosquito-borne infectious diseases, have a vaccine or a cure method, but when they infect, the mortality rate is high and the incidence of aftereffects is high.

In addition, dengue fever, West Nile fever, and chikavirus infections, which are infectious mosquito infectious diseases, are not suitable vaccines or therapies.

Therefore, the best way to prevent mosquito-borne infectious diseases is not to be bitten by mosquitoes, and the importance of mosquito control is increasing day by day.

Especially, port cities such as Incheon and Busan have a lot of logistics flows from overseas and foreign mosquitoes can flow into them, which makes mosquito control more important.

Currently, the mosquito control system selects mosquito bundles (vulnerable areas) by combining the recommendation of government offices such as resident center (government office), reference of past selected area, field environmental survey and complainant's declaration, but this method is subjective and continuous There was a limit to apply to mosquito control site.

Korean Patent No. 10-1001317

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems and it is an object of the present invention to provide a mosquito control system and a mosquito control method, The present invention provides a mosquito control system with improved mosquito function.

According to a first embodiment of the present invention for solving the above problems,

A mosquito meter installed in a plurality of mosquito monitoring areas and measuring the number of mosquitoes in each mosquito monitoring area;

A storage DB for receiving and storing the mosquito measurement number from the mosquito meter; A calculation module for calculating an average value of the mosquito measurement counts and storing the calculated average value in a storage DB; When the average value of the average number of mosquitoes measured in the storage DB is compared with the average value of the number of mosquitoes measured in the real time, A mosquito generation class applying object selection module for comparing the number average value and the real time mosquito measurement number average value and selecting the real time mosquito measurement number as a mosquito generation class application object when the average value of the real time mosquito measurement number exceeds the normal mosquito measurement number average value; If the normal mosquito measurement number is selected as the mosquito generation class application target, the range of the maximum mosquito number in the normal mosquito measurement range is divided into 0 to set the mosquito generation class. If the real-time mosquito measurement number is selected as the mosquito generation class application target A mosquito generation class setting module for setting a mosquito generation class by dividing a range from the maximum number of mosquitoes in the real-time mosquito measurement number to 0; A mosquito generation class application module for comparing the number of real-time measurement mosquitoes of each mosquito monitoring area with the mosquito generation class set by the mosquito generation class setting module and selecting a class of each mosquito monitoring area; A mosquito control management server having a mosquito generation map production module for producing a mosquito generation map by linking the grade of the mosquito monitoring area with the geographical information;

A portable terminal for receiving a mosquito generation map from the mosquito control management server,

And a control unit.

Further, in the second embodiment of the present invention,

In the first embodiment,

The average value of mosquitoes measured in each mosquito monitoring area is stored in the storage DB,

Wherein the mosquito control management server comprises:

If the average value of the mosquito monitoring area in the mosquito monitoring area exceeds a preset reference value, the first priority control area selecting module for selecting the mosquito monitoring area as the priority control area irrespective of the mosquito generation class selection according to the mosquito generation class application module Further comprising:

Further, in the third embodiment of the present invention,

In the first embodiment,

The mosquito measuring instrument further includes a camera installed around the suction port of the mosquito meter to photograph a mosquito flowing into the suction port,

The storage DB of the mosquito control management server stores a mosquito image from a camera of the mosquito meter,

The mosquito control management server includes a risk mosquito class setting module for setting a rating of a dangerous mosquito; a mosquito type analysis module for analyzing a mosquito image of each mosquito monitoring area mosquito image by analyzing a mosquito image from a camera of each mosquito meter; If the mosquito type analyzed by the mosquito type analysis module is a dangerous mosquito set by the dangerous mosquito class setting module, the mosquito monitoring area where the mosquito is photographed is selected as the priority control area regardless of the mosquito generation class selection according to the mosquito generation class application module And a second priority control area selection module for selecting the order of the priority control areas in order of the risk mosquito class set by the risk mosquito class setting module.

The present invention can perform a mosquito control work about a vulnerable area first by installing a plurality of mosquito meters in a mosquito emergence area, performing real-time mosquito measurement for a mosquito emergence area, and selecting a mosquito control priority area, There is an effect that the mosquito can be effectively controlled.

Accordingly, the present invention can minimize the damage of livestock and people caused by the occurrence of mosquitoes, and it is possible to minimize damage to domestic animals caused by mosquitoes such as Japanese encephalitis, malaria-induced mosquitoes, domestic dengue fever, West Nile fever, Induced mosquitoes can be prevented from direct contact with humans, which can effectively reduce the incidence of such diseases, where the mortality rate and sequelae are severe. Furthermore, in port cities such as Incheon and Busan, there is a high possibility that foreign influenza-causing mosquito infectious disease-inducing mosquitoes that do not have a proper vaccine or a treatment method are inflowed. However, such an effective mosquito control as the present invention can reduce such concern.

1 is a view for explaining a configuration of a mosquito control system according to a first embodiment of the present invention,
2 is a diagram for explaining a communication flow of the mosquito control system according to the first embodiment of the present invention,
3 is a view for explaining mosquito measurement according to the mosquito control system according to the first embodiment of the present invention,
FIG. 4 is a diagram for explaining mosquito generation map production according to the mosquito control system according to the first embodiment of the present invention,
5 is a diagram showing that a real-time mosquito measurement number is displayed on a mosquito generation map,
FIG. 6 is a view for explaining a concentrated area concentration control,
7 is a view for explaining a configuration of a mosquito control system according to a second embodiment of the present invention,
8 is a diagram for explaining a configuration of a mosquito control system according to a third embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

FIG. 1 is a view for explaining a configuration of a mosquito control system according to a first embodiment of the present invention. Referring to FIG. 1, the configuration of a mosquito control system according to a first embodiment of the present invention will be described.

As shown in FIG. 1, the mosquito control system according to the first embodiment of the present invention includes a mosquito meter 100, a mosquito control management server 200, and a portable terminal 300.

The mosquito meter 100 is installed in a plurality of mosquito monitoring areas, and measures the number of mosquitoes in each mosquito monitoring area in real time. At this time, the mosquito measuring instrument 100 can measure the mosquito while collecting or collecting the mosquito. In the present embodiment, the mosquito meter 100 can be applied to various mosquito meters known in the art for measuring the number of mosquitoes.

The mosquito control management server 200 includes a storage DB 201, a calculation module 202, a mosquito generation class application target selection module 203, a mosquito generation class setting module 204, (205), and a mosquito generation map production module (206).

The storage DB 201 receives and stores the mosquito measurement number from the mosquito meter 100. In this embodiment, the storage DB 22 can receive the mosquito measurement number through the Internet network, and if necessary, a separate communication network is provided between the mosquito meter 100 and the storage DB 201, The number of the mosquito measurement can be received.

The calculation module 202 calculates an average value of the mosquito measurement counts and stores the average value in the storage DB 201.

Here, the average value of the mosquito measurements is calculated by the following equation.

[Equation 1]

S _n = (C ₁ + C ₂ + C ₃ + ... C _{n - 1} + C _n ) / n

{S _n is average value of mosquito measurement number, C ₁ ~ C _n is mosquito measurement number per mosquito monitoring area, n is mosquito monitoring area number}

The mosquito generation class application target selection module 203 compares the average number of mosquitoes measured in the normal DB of the storage DB 201 with the average value of the mosquito measurements in the real time and if the average value of the real number mosquito measurements is below the normal mosquito count average value, If the number of mosquitoes is higher than the average number of mosquitoes, the real-time mosquito count will be applied to the mosquito generation rate Select the target.

The normal year refers to the previous year period corresponding to the mosquito real time measurement period.

For example, if the mosquito real time measurement period is a predetermined time (for example, 22 to 23 hours) during a day on May 1, 2017, the normal year may be a certain time during the day on May 1, 2016 ~ 23 hours). Also, if the mosquito real time measurement period is 1 day on May 1, 2017, the normal year is 1 May 2016. Also, if the real-time measurement of mosquitoes is from April 25, 2017 to May 1, 2017 (one week), the normal year is from April 25, 2016 to May 1, 2016 (one week).

The mosquito generation class setting module 204 sets the mosquito generation class by dividing the range from the maximum number of mosquitoes in the normal mosquito measurement number to 0 when the normal mosquito measurement number is selected as the mosquito generation class application target.

For example, if the number of mosquitoes per year in a region is 20, a region b is 40, a region c is 70, a region d is 90, and a region e is 100, 100 to 75, 3 to 51 to 75, 4 to 26 to 50, and 5 to 0 to 25).

The mosquito generation class setting module 204 sets a mosquito generation class by dividing the range from the maximum number of mosquitoes among the real-time mosquito measurement numbers to zero when the real-time mosquito measurement number is selected as the mosquito generation class application target.

For example, if the number of real-time mosquitoes in each region is 20, b = 40, c = 70, d = 90, and e = Grade: 110 ~ 88, 2 grade: 87 ~ 66, 3 grade: 44 ~ 65, 4 grade: 22 ~ 42, 5 grade: 0 ~ 21).

The mosquito generation class application module 205 compares the number of real-time measurement mosquitoes of each mosquito monitoring area with the mosquito generation class set by the mosquito generation class setting module 204 to select a class of each mosquito monitoring area.

For example, if a mosquito generation class is set to a mosquito generation class set according to the number of real-time measurement mosques, a mosquito generation class is applied according to the number of real-time mosques in each mosquito monitoring area (a region: grade 5, region b: grade 4 , area c: grade 2, area d: grade 1, e area: grade 1).

In addition, if the mosquito generation class is set as the mosquito generation class set in accordance with the normal mosquito count, the mosquito generation class is applied according to the normal mosquito number of each mosquito monitoring area (a region: grade 5, region b: class 4, c Area: 3 ranks, d area: 2 ranks, e area: 1 ranks).

The mosquito generation map production module 206 links the mosquito monitoring area with the geographical information to produce a mosquito generation map.

The portable terminal 300 receives the mosquito generation map from the mosquito control management server 200 and outputs it in an identifiable manner. In this embodiment, the portable terminal 300 may be a smart phone, a tablet PC, a notebook computer, or the like.

In this embodiment, the portable terminal 300 communicates with the mosquito control management server 200 via the Internet network or, if necessary, a separate communication network is provided between the portable terminal 300 and the mosquito control management server 200 , And can communicate with each other through the communication network.

FIG. 2 is a view for explaining the communication flow of the mosquito control system according to the first embodiment of the present invention, FIG. 3 is a view for explaining mosquito measurement according to the mosquito control system according to the first embodiment of the present invention FIG. 4 is a diagram for explaining production of a mosquito generation map according to the mosquito control system according to the first embodiment of the present invention, FIG. 5 is a diagram showing that a real-time mosquito measurement number is displayed on a mosquito generation map, The operation of the first embodiment according to the present invention will now be described with reference to FIGS. 2 to 6 as follows.

The mosquito meter 100 installed in each of the plurality of mosquito monitoring areas measures the number of mosquitoes in each mosquito monitoring area as shown in FIG. 3 and sends them to the mosquito control management server 200.

Then, the storage DB 201 of the mosquito control management server 200 receives and stores the number of mosquito measurements received from each mosquito meter 100.

At this time, the calculation module 202 of the mosquito control management server 200 calculates a real-time mosquito measurement number average value of a plurality of mosquito monitoring areas using Equation (1).

On the other hand, the storage DB 201 of the mosquito control management server 200 stores average values of mosquitoes counted in the normal mosquito monitoring area. Here, the average value of mosquito counts in normal years is calculated using Equation 1.

When the average mosquito count average value and the real-time mosquito count average value are prepared as described above, the mosquito generation class application target selection module 203 compares the average mosquito count average value of the storage DB 201 with the real- If the average value of the mosquito measurement number is below the normal mosquito measurement number average value, the average mosquito measurement number average value is compared with the normal mosquito measurement number average value, If the measured number average value is exceeded, the real-time mosquito measurement number is selected as the mosquito generation class application target.

Then, the mosquito generation class setting module 204 sets a mosquito generation class by dividing the range from the maximum number of mosquitoes in the normal mosquito measurement number to 0 when the normal mosquito measurement number is selected as the mosquito generation class application target, If the mosquito measurement number is selected for the mosquito generation class, the mosquito generation class is set by dividing the range from the maximum number of mosquitoes in the real-time mosquito measurement number to zero.

Then, the mosquito generation class application module 205 compares the number of real-time measurement mosquitoes of each mosquito monitoring area with the mosquito generation class set by the mosquito generation class setting module 204, and selects a class of each mosquito monitoring area.

Then, the mosquito generation map production module 206 produces a mosquito generation map showing the mosquito generation grade as shown in FIG. Here, the mosquito control management server 200 may include a display to confirm a mosquito generation map through a display. At this time, the mosquito generation number to be measured in real time as shown in FIG. 5 can be displayed on the mosquito generation map outputted on the display.

Subsequently, when a mosquito generation map showing the mosquito generation grade is produced, the mosquito control management server 200 sends the mosquito generation map to the portable terminal 300 held by the person in charge of control.

Then, the person in charge of the control can preferentially concentrate the vulnerable area through the portable terminal 300 as shown in FIG. 6, thereby effectively performing the mosquito control.

Meanwhile, the data communication in this embodiment has sufficient security through data encryption, a firewall and the like as shown in FIG.

FIG. 7 is a diagram for explaining a configuration of a mosquito control system according to a second embodiment of the present invention. Referring to FIG. 7, a second embodiment of the present invention will be described below.

In the second embodiment according to the second embodiment of the present invention, in the storage DB 201, an average value for each mosquito monitoring county for each mosquito monitoring area is stored.

Here, the average value of the mosquito monitored area in the mosquito monitoring area is calculated by the following equation.

[Equation 2]

S _n = (C ₁ + C ₂ + C ₃ + ... C _n-1 + C _n ) / n

{S _n is the mean value of mosquito monitoring in the mosquito monitoring area, C ₁ ~C _n is the number of mosquitoes per year, and n is the number of years}

For example, if the real-time mosquito measurement time is May 1, 2017, the average value of the mosquito measurement years is the value obtained by dividing the total number of mosquito measurements on May 1, 2010 to 2017 by 8.

The mosquito control management server 200 monitors mosquitoes generated by the mosquito generation class application module 205 when a normal average value of mosquito monitoring years in a predetermined mosquito monitoring area among a plurality of mosquito monitoring areas exceeds a preset reference value And a first priority control area selection module 207 for selecting the predetermined mosquito monitoring area as a priority control area irrespective of the grade selection.

Here, the predetermined reference value may be arbitrarily set, and the control area selection module 27 selects the mosquito monitoring area as the priority control area if the average value of the mosquito measurement water year is greater than the reference value.

For example, if the reference value is 30 and the normal average value of the mosquito measurement year is 50, the mosquito monitoring area is selected as the priority control area. At this time, the control area selection module 27 ignores the mosquito generation class application module 205, and selects the control area as a priority control area.

FIG. 8 is a view for explaining a configuration of a mosquito control system according to a third embodiment of the present invention, and a third embodiment of the present invention will be described with reference to FIG.

The third embodiment of the present invention is characterized in that the mosquito meter 100 according to the third embodiment of the present invention is installed in the vicinity of the suction port 120 of the mosquito measuring instrument 100 to detect the mosquitoes flowing into the suction port 120 (110).

At this time, the camera 110 captures a mosquito and sends it to the mosquito control management server 200.

The storage DB 201 of the mosquito control management server 200 stores a mosquito image from the camera 110 of the mosquito meter.

The mosquito control management server 200 further includes a risk mosquito class setting module 208 for setting a rating of the dangerous mosquitoes and a mosquito control module for analyzing the mosquito images from the cameras 110 of the mosquito meters 100, If the mosquito type analyzed by the mosquito type analysis module 209 and the mosquito type analysis module 209 for analyzing the mosquito type of the mosquito image is the dangerous mosquito set by the dangerous mosquito class setting module 208, The monitoring area is selected as a priority control area regardless of the selection of the mosquito generation class according to the mosquito generation class application module 205 and the priority order of the priority control areas is selected as the danger mosquito class set in the risk mosquito class setting module 208 And a second preference control area selection module 210 for selecting the first preference control area.

Here, an example of a method for the mosquito control management server 200 to select a control area will be described as follows.

First, the risk mosquito class setting module 208 sets the risk level of the mosquito according to the operator inputting the risk level according to the type of the mosquito. For example, white-mosquito mosquitoes (chickavirus-infected mosquitoes, dengue-mosquito-borne mosquitoes) may be at a first-degree of risk, and Chinese spotted mosquitoes (malaria-mediated mosquitoes) may be at a second-degree of risk.

At this time, the mosquito type analysis module 209 analyzes a mosquito image from the camera 110 of each mosquito meter 100, and analyzes the mosquito type of each mosquito monitoring area mosquito image.

Then, the second preferential treatment area selection module 210 includes a Chinese spotted mosquito in the mosquito type of area A analyzed by the mosquito type analysis module 209, and a white mosquito mosquito is included in the mosquito type of area D The region D is set as the first preference control area and the area A is set as the second preference control area regardless of the selection of the mosquito generation class according to the mosquito generation class application module 205, The remaining mosquito surveillance area shall be classified as a subordinate to the first and second priority control areas.

However, when the second embodiment is applied to the present embodiment, the mosquito generation class application module 205 of the first and second embodiments may be applied to the mosquito generation class application module 205, The second prefered treatment area selection module 210 of the present embodiment can preferentially select the treatment area in preference to the occurrence grade selection.

The mosquito control of the present embodiment of the present invention can be used to rapidly control mosquito blooms of foreign inflowing mosquitoes such as white mosquito mosquitoes, etc., when white mosquito mosquitoes are introduced due to inflow of overseas logistics such as Incheon and Busan And it is possible to prevent a disease such as Chikavirus infection from occurring.

According to the first embodiment of the present invention, the mosquito measurement count can be grasped in real time, and the mosquito control priority area corresponding to the current mosquito appearance state can be determined, thereby effectively performing the mosquito control.

In addition, the first embodiment of the present invention compares the average value of the mosquito counts measured in the normal years with the average value of the mosquito measurements in the real time, and if the average value of the real-time mosquito counts is less than the average mosquito count average value, , It is possible to compensate for the error of the real-time mosquito measurement or the error of the measurement of the mosquito number due to the temporary decrease in the number of mosquitoes.

The first embodiment of the present invention compares the average value of the average number of mosquitoes measured with the average value of the average number of mosquitoes measured in the past and the average value of the number of mosquitoes measured in the real time. By using the numerical data, it is possible to efficiently perform mosquito control according to an increase in the number of real-time mosquitoes.

In addition, the second embodiment of the present invention uses the mosquito data (average value of mosquitoes measured in years) which are more widely and stabilized, By selecting the area, mosquito control can be done more efficiently.

In the third embodiment of the present invention, mosquito control can be performed more efficiently by selecting a priority control area according to the type of mosquito irrespective of the selection of a mosquito generation class according to the mosquito generation class application module 205.

According to the first to third embodiments of the present invention, a plurality of mosquito meters 100 are installed in a mosquito emergence area, real-time mosquito measurement is performed on a mosquito emergence area, mosquito control priority areas are selected, The mosquito control can be performed first, and the mosquito can be efficiently controlled in a short time.

Accordingly, the present invention can minimize the damage of livestock and people caused by the occurrence of mosquitoes, and it is possible to minimize damage to domestic animals caused by mosquitoes such as Japanese encephalitis, malaria-induced mosquitoes, domestic dengue fever, West Nile fever, Induced mosquitoes can be prevented from direct contact with humans, which can effectively reduce the incidence of such diseases, where the mortality rate and sequelae are severe. Furthermore, in port cities such as Incheon and Busan, there is a high possibility that foreign influenza-causing mosquito infectious disease-inducing mosquitoes that do not have a proper vaccine or a treatment method are inflowed. However, such an effective mosquito control as the present invention can reduce such concern.

Accordingly, the present invention is highly industrially applicable, and when applied to a mosquito control industry, it can secure health and safety, and can generate economic profitability.

While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, but, on the contrary, And it goes without saying that the invention belongs to the scope of the invention.

100; Mosquito meter 110; camera
200; A mosquito control management server 201; Storage DB
202; A calculation module 203; Mosquito Generation Class Applicable Selection Module
204; A mosquito generation class setting module 205; Mosquito Generation Application Module
206; Mosquito generation map generation module 207; First priority control area selection module
208; Risk mosquito class setting module 209; Mosquito type analysis module
210; A second preference control area selection module 300; Portable terminal

Claims (3)

A mosquito meter installed in a plurality of mosquito monitoring areas and measuring the number of mosquitoes in each mosquito monitoring area;
A storage DB for receiving and storing the mosquito measurement number from the mosquito meter; A calculation module for calculating an average value of the mosquito measurement counts and storing the calculated average value in a storage DB; When the average value of the average number of mosquitoes measured in the storage DB is compared with the average value of the number of mosquitoes measured in the real time, A mosquito generation class applying object selection module for comparing the number average value and the real time mosquito measurement number average value and selecting the real time mosquito measurement number as a mosquito generation class application object when the average value of the real time mosquito measurement number exceeds the normal mosquito measurement number average value; If the normal mosquito measurement number is selected as the mosquito generation class application target, the range of the maximum mosquito number in the normal mosquito measurement range is divided into 0 to set the mosquito generation class. If the real-time mosquito measurement number is selected as the mosquito generation class application target A mosquito generation class setting module for setting a mosquito generation class by dividing a range from the maximum number of mosquitoes in the real-time mosquito measurement number to 0; A mosquito generation class application module for comparing the number of real-time measurement mosquitoes of each mosquito monitoring area with the mosquito generation class set by the mosquito generation class setting module and selecting a class of each mosquito monitoring area; A mosquito control management server having a mosquito generation map production module for producing a mosquito generation map by linking the grade of the mosquito monitoring area with the geographical information;
A portable terminal for receiving a mosquito generation map from the mosquito control management server,
Wherein the mosquito control system comprises:
The method according to claim 1,
The average value of mosquitoes measured in each mosquito monitoring area is stored in the storage DB,
Wherein the mosquito control management server comprises:
If the average value of the mosquito monitoring area in the mosquito monitoring area exceeds a preset reference value, the first priority control area selecting module for selecting the mosquito monitoring area as the priority control area irrespective of the mosquito generation class selection according to the mosquito generation class application module Further comprising the step of controlling the mosquito control system.
The method according to claim 1,
The mosquito measuring instrument further includes a camera installed around the suction port of the mosquito meter to photograph a mosquito flowing into the suction port,
The storage DB of the mosquito control management server stores a mosquito image from a camera of the mosquito meter,
The mosquito control management server includes a risk mosquito class setting module for setting a rating of a dangerous mosquito; a mosquito type analysis module for analyzing a mosquito image of each mosquito monitoring area mosquito image by analyzing a mosquito image from a camera of each mosquito meter; If the mosquito type analyzed by the mosquito type analysis module is a dangerous mosquito set by the dangerous mosquito class setting module, the mosquito monitoring area where the mosquito is photographed is selected as the priority control area regardless of the mosquito generation class selection according to the mosquito generation class application module And a second priority control area selecting module for selecting the order of the priority control areas in order of the risk mosquito class set by the risk mosquito class setting module.

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