KR20040020833A - A remote monitoring system for exterminating pest and a method thereof - Google Patents

Abstract

PURPOSE: A remote monitoring system for pest prevention and a method for monitoring the same in remote are provided to analyze the information of the pest by seizing the information of the pest by various categories. CONSTITUTION: A remote monitoring system for pest prevention includes at least one detection sensor, at least one remote controller and a control and reporting center(200). The detection sensor is installed at a plurality of regions by dividing the monitoring target and monitors the movement of the pest in each of the divided regions. The detection sensor generates a detection signal in response to the monitored result and transmits the generated detection signal. The remote controller is installed on the target object and receives the monitoring signal. The remote controller processes the received sensing signal and transmits the processed sensing signal. And, the control and reporting center(200) receives the information transmitted from the remote controller and analyzes and manages the received information for each of the divided regions.

Description

Remote monitoring system for control and remote monitoring method {A REMOTE MONITORING SYSTEM FOR EXTERMINATING PEST AND A METHOD THEREOF}

The present invention relates to a remote monitoring system and method for controlling the same, and particularly for remote control to capture and monitor the penetration or movement of pests, seawater (rats, weasels, etc.) or seaweed, and to eradicate or combat or prevent them. A remote monitoring system and method thereof are provided.

Insects such as cockroaches and ants, seawater such as rats and weasels, or seaweeds penetrate houses and buildings, destroy buildings and facilities, disgust residents, and carry huge germs and pathogens. Is causing. Accordingly, various solutions have been proposed to combat the infestation of pests or pests that have already invaded. (In this specification, pests are referred to collectively as pests, seawater, seaweed, etc.) if necessary.

In the conventional control method, the person performing the control (hereinafter referred to as "control person in charge") visits the building ("control object") in person, grasps the situation by means of direct investigation, resident interview, etc., and then performs the control accordingly. It was. According to the conventional method, the detailed information on the ecology of the pest, such as the path of penetration of the pest that penetrates the predetermined building to be controlled, the place of activity, the type, and the drug that has become resistant, can be visited by visiting the building to be controlled. There was a problem that can not be identified until. In the case of establishing such countermeasures by acquiring such information through visits, there is a problem that not only a lot of manpower and cost are generated but also the amount or reliability of the information and the efficiency of the control depend on the person in charge who controls the information. .

In order to solve this problem, automated systems have been proposed to identify the situation without the visitor directly visiting the building to be controlled. However, the proposed systems lack the configuration to perform the effective control. In particular, the appearance and activity of pests in a single controlled building depends on the characteristics of each zone. In the conventional control methods and systems, the characteristics of these zones have not been considered for control. Therefore, even if the information for pest control is obtained, there is a problem that the information is not managed systematically according to the detailed area within the building, the efficiency of the control work is reduced. For example, the control person visits the building again to reconsider the location where the pests were detected, or the same control measures for all buildings, despite the inefficiency and overuse of drugs and the appearance of pests in some areas. Should be applied.

An object of the present invention is to provide a system and method for systematically grasping and managing information on the ecology and control history of pests in a building to be controlled.

In addition, an object of the present invention is to provide a remote monitoring system for control that can centrally manage the information on the ecology and control of pests collected for each building to be controlled remotely.

In addition, an object of the present invention is to provide a remote monitoring method for the control to perform effective control activities by collecting and managing information on the ecology of the pest according to the block in the building to be controlled.

Other features and objects of the present invention will be described in detail in the configuration and claims of the invention below.

1 is a schematic diagram conceptually showing a configuration of a remote monitoring system for control according to a first embodiment of the present invention.

Figure 2 is a schematic diagram showing the interrelationship of a sensor, a repeater, a remote controller and a central control device according to an embodiment of the present invention.

3 shows an example of partitioning according to an embodiment of the invention.

4 is a block diagram conceptually illustrating a configuration of an embodiment of a remote monitoring apparatus included in the remote monitoring system of FIG.

5 is a block diagram conceptually illustrating a configuration of an embodiment of a central control apparatus included in the remote monitoring system of FIG.

6 is a table showing the results of analysis on the activity of cockroaches in one subdivision.

7A to 7C are alarm tables used when the control point determination module determines the control point.

8 is an application table for determining which table should be applied according to subdivision codes.

9A and 9B conceptually illustrate one embodiment of a report generated by a central control apparatus included in the remote monitoring system of FIG.

FIG. 10 is a flowchart conceptually illustrating main operations of a remote monitoring apparatus of the remote monitoring system of FIG. 1; FIG.

FIG. 11 is a flowchart conceptually illustrating main operations of the central control apparatus of the remote monitoring system of FIG. 1; FIG.

12 is a schematic diagram conceptually showing a configuration of a remote monitoring system for control according to a second embodiment of the present invention.

13 is a schematic diagram conceptually showing a configuration of a central control apparatus according to a second embodiment of the present invention.

Fig. 14 is a schematic diagram conceptually showing the configuration of a remote monitoring system for control according to a third embodiment of the present invention.

15 is a schematic diagram conceptually showing the configuration of a remote monitoring apparatus according to a third embodiment of the present invention;

*** Explanation of symbols for the main parts of the drawing ***

10, 12, 14: building 70: portable communication terminal

200: central control device 300: wireless communication network

400: wired communication network 900: receiving module

910: transmission module 920, 1020: position search module

1002: detection sensor 1004, 2012: communication module

1006: detection information processing module 1010: repeater

1011: transmission time determination module 2014: response time determination module

1016: terminal connection module 2010: database

1018, 2002: Pest Information Analysis Module

2006: Pest Information Module 2008: Report Preparation Module

In order to achieve the above object, the present invention is installed in a plurality of partitioned zone of the monitoring object to detect at least one movement of pests in each zone and generates and transmits a detection signal according to the at least one sensor; At least one remote controller installed in the monitoring object and configured to receive the detection signal and process and transmit the received detection signal; And it provides a remote monitoring system for the control comprising a central control device for receiving and receiving information transmitted from the remote controller for analysis and operation for each zone.

The remote controller includes a receiving module for receiving a detection signal from the detection sensor; A sensing information processing module which receives the sensing signal from the receiving module and processes the sensing signal to collect the pest related information; And a transmission module for transmitting the processed pest related information to the central control apparatus.

The remote controller may further include: a transmission time determining module configured to determine whether to immediately transmit the pest related information; And a memory for storing a result of processing the pest-related information for a predetermined period until the pest-related information is transmitted if the transmission time determining module determines that the pest-related information is not immediately transmitted.

The central control device includes a pest related information analysis module for receiving and analyzing pest related information transmitted from the remote monitoring device; A pest related information operation module configured to store, update, and operate a pest related information transmitted from the remote monitoring apparatus as a database; A database operated by the pest related information operation module; A control time determination module that determines whether to execute a control operation immediately based on the information analyzed by the pest related information analysis module; And a communication module for performing a wired or wireless communication function.

The related information analysis module assigns a rating to each detection sensor according to the detected number of pests, and the control time determination module determines the control time of the zone based on the rating of the detection sensor in each zone. desirable.

In addition, the present invention comprises the steps of partitioning the monitoring object into a plurality of zones to achieve the above object; Collecting pest-related information active in each compartment; Transmitting the collected pest related information to the central control apparatus; Analyzing the transmitted pest related information; Updating and storing the analyzed pest related information in comparison with information previously stored in a database; And determining a time for controlling the pest based on the analyzed pest related information.

The partitioning step may include partitioning the monitored object into a physical area.

Alternatively, the dividing may include dividing each area within the monitored object according to its function.

The dividing may include dividing each region in the monitored object into the minimum unit in which the control is performed.

The step of assigning a code to each area of the minimum unit and analyzing the pest related information may include arranging pest related information for each code for each area of a plurality of monitored objects.

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

1 is a schematic diagram conceptually showing the configuration of a remote monitoring system for control according to a first embodiment of the present invention.

As shown, the remote monitoring system for control according to an embodiment of the present invention, is installed in each building (10, 12, 14) to be monitored to monitor the activity of pests and collect information about them, and wireless communication network 300 or the remote monitoring device 100 for transmitting the collected information through a wired communication network 400, such as the Internet or a general telephone network, and concentrates and receives information about the pest transmitted from the remote monitoring device 100 and It includes a central control device 200 for analyzing and operating the received information. In the present specification, the object to be monitored means a building or other predetermined space (for example, a concept including a park, a cargo loading space, etc.) and the outside where the pests may or may appear.

Remote monitoring device 100 installed in each building (10, 12, 14) monitors the activity of pests, information such as the number of infested or trapped by the type of pest, infiltration time, infiltration path, infiltration site Collect pest information). The collected pest-related information is preferably collected using a predetermined sensor suitable for detecting each pest according to the type of pests expected to be penetrated or active. Details of the detection sensor will be described later with reference to FIG. 4.

The collected pest related information is transmitted to the central control apparatus 200 in real time or periodically through the wireless communication network 300 or the wired communication network 400. The communication network may select a suitable one such as a general telephone network, a cable for high-speed Internet, a wireless LAN, etc. according to the type and state of each building 10, 12, 14 in which the remote monitoring apparatus 100 is installed.

The central control apparatus 200 receives pest related information transmitted from the remote monitoring apparatus 100 and analyzes them. Pest-related information is analyzed to grasp the information such as the frequency of appearance, appearance, or the number of catches according to a predetermined analysis category, such as by the monitored building, the location within a particular building, the date and time, and the type of pest. It is desirable to be. Details thereof will be described later with reference to FIGS. 5 and 6. Countermeasures against pests generated in the building are prepared by the information analyzed by the central control apparatus 200. In this case, the countermeasures may be prepared for each kind of pests. According to the above measures, if it is determined that the control is necessary, the control personnel go to the corresponding building and perform appropriate control operations based on the analyzed information.

The central control apparatus 200 derives secondary information to help control, such as to determine the appropriate control time, such as to store the database, stored, updated and analyzed as necessary, the pest-related information, and if necessary You may also write your report on a regular or occasional basis. In this specification, a place where the central control apparatus 200 is installed will be referred to as a central control center.

The interrelation between the sensor 1002, the repeater 1010, the remote controller 1004 and the central control apparatus 200 is shown in FIG. The repeater 1010 may be installed to efficiently perform wireless communication between the sensor 1002 and the remote controller 1004. One or more detection sensors 1002 are connected to one repeater 1010, and the remote monitoring apparatus 100 is configured in a structure in which one or more repeaters are connected to one remote controller 1004.

In the present invention, in order to effectively manage the pest related information, the remote monitoring object is divided into a plurality of zones. Partitioning means dividing the monitored object including the building into a plurality of zones in a hierarchical manner according to the characteristics of the place. In one embodiment of the present invention, the monitored object is divided into four stages. The partitioning of the four stages of the embodiments described in this specification may be classified into the largest classification, such as each building (each building) and its perimeter, a large classification, a floor classification for each building, It is divided into subclasses, subclasses, and subclasses below. Subdivisions are the smallest units that can be partitioned. Subdivisions are further subdivided when new areas need to be managed. Taking a factory as an example, as shown in FIG. 3, the major classification is a building such as a production building and a warehouse building in the factory, and the exterior and floor classification are each floor of the building (basement 1 floor, 1 floor, 2 floors, 3 floors). , Roof), and middle classification are production line 1, production line 2, production line 3, and subdivision in production line, storage, aging room, and toilet in each line. Such a hierarchy of classifications may be, for example, a unit of control work (for example, a subdivision, usually a subdivision according to a subdivision, becomes a minimum unit of control work), and a unit of preparing a countermeasure. It is used to analyze and manage pest information. For example, it is possible to analyze the trend of pest incidence and the effects of the control measures for each line of the middle classification, and use the information when modifying or expanding the line, so that appropriate control measures and related equipment can be provided for each line.

Each subdivision, which is a unit of subdivision, is assigned a subdivision code. Subdivision code refers to a code that classifies and assigns remote facilities by function or by trend of pest occurrence. Even if they are not the same subdivision, it can be predicted that the pest tendency will be similar if the subdivision codes are identical. Even if the subdivisions are different subdivisions, the subdivision codes assigned to them may be the same. For example, computer rooms and offices in an office building may have different subdivisions, but may have the same subdivision code because they have similar characteristics in terms of control operations and thus control operations are similar. In addition, even if the subdivisions are the same subdivisions, different subdivision codes may be assigned in consideration of the upper subdivision, stratification, and major classification. For example, the kitchen of a general home and the kitchen of a large restaurant have the same subdivision, but since the characteristics of the building are completely different, the subdivision code can be given differently. Even if the structure to be controlled is complicated by various subdivisions, using subdivision codes makes it easy to identify which subdivisions of what nature or function are being monitored and to quickly establish appropriate control measures. It is possible.

In the embodiment of the present invention, the object to be monitored is divided based on a physical unit (for example, each floor, a production line, etc.) already present in a building, etc., but the criteria for partitioning are not limited thereto. For example, the classification may be classified according to whether wireless communication is appropriate or wired communication is appropriate. In the case of a department store, for example, the first space in which the stores are located has partitions to distinguish each store, and thus there are many obstacles to wireless communication. There are no communication obstacles. In this case, the first and second spaces may be determined according to a communication method, and with reference thereto, the first space may be installed with a wired communication sensor, and the second space may be installed with a wireless communication sensor. This classification allows the control staff to systematically install the necessary sensors in each zone of the monitored object.

4 is a block diagram conceptually illustrating a configuration of an embodiment of a remote monitoring apparatus 100 included in the remote monitoring system for control of FIG. 1.

As shown, the remote monitoring device 100 is installed at a predetermined position of the monitored building 10, 20, 30 to detect one or more activity of the pest and generate a detection signal accordingly. And a remote controller 1004 for receiving a detection signal from the detection sensor 1002 and processing the received detection signal to transmit the processed signal through a wired or wireless communication network. Here, the "detection signal" is a signal indicating whether a pest has been detected, and means a signal generated by the detection sensor 1002 and transmitted to the remote controller 1004. In FIG. 4, the solid line between the sensor n 1002.n and the repeater 1010 indicates a wired communication network, and in FIG. 4, a lightning bolt represents a wireless communication network.

The detection sensor 1002 may determine its installation location and number according to the characteristics of each zone of the partitioned building 10, 20, 30. In addition, the type of the sensor 1002 installed in one building (10, 20, 30) may be one or more. That is, a detection sensor 1 (1002.1) for detecting the movement of cockroaches as a pest, a detection sensor 2 (1002.2) for detecting the movement of mosquitoes or flies as a fly pest, and a detection sensor for detecting the movement of a mouse as seawater It is preferable to appropriately install various kinds of sensing sensors 1002 such as n (1002.n). In the embodiment of the present invention, by installing the detection sensor 1002, it is possible to measure the activity of pests in the monitored object. The detection sensor 1002 may be implemented by adding a sensor such as a heat detector or a motion detector to, for example, a known catching equipment, an attracting insect lamp, an automatic drug spray device, a rodent attraction trapping frame, and the like. In addition, the sensor 1002 may be installed with the control equipment attached to the sticky. By using such equipment to measure the population of attracted or trapped pests. Measure the activity of the pest.

The installation location and the number of the detection sensor 1002 is determined according to the type and number of pests to be controlled at the location, which may be mainly determined by the ecology of the pest and the condition and location of the particular building. The type, position, and number of the detection sensors 1002 may be determined based on the subdivision code assigned to each divided zone.

In the present invention, it becomes easy to analyze, use, and manage the pest-related information generated by the location management of the detection sensor 1002 and the detection sensor 1002 installed in each zone through partitioning. Without partitioning, management is performed in a cumbersome manner, such as drawing the position of the sensor 1002 in the drawing of the object to be monitored or displaying it in absolute or relative coordinate values. However, according to the remote monitoring system according to an embodiment of the present invention, since the position of the sensor 1002 installed in the object to be monitored is stored in the central control apparatus 200 together with the information of each section partitioned, the position of the sensor 1002. Can be identified and used easily and accurately. If the location of the detection sensor 1002 is not known, accurate pest information may not be obtained, and pests may be trapped in the control equipment and left for a long time to become habitats of new pests.

In addition, in the present invention, as well as the location and number of the detection sensor 1002 installed in each zone by partitioning, the pest-related information generated by each detection sensor 1002 is managed in conjunction with the partitioning information, so that the pest-related information is partitioned. Can be managed and analyzed in units. Therefore, it is possible to derive information useful for controlling each control unit area effectively from the pest related information.

The detection sensor 1002 generates a detection signal in response to the detection of the pest. The generated detection signal is transmitted to the remote controller 1004 wirelessly or by wire, along with identification code and time information unique to the detection sensor 1002 for identifying the detection sensor 1002.

The sensing signal may be transmitted from the sensing sensor 1002 to the remote controller 1004 via the repeater 1010. In particular, the repeater 1010 is required when the buildings 10, 12 and 14, which are monitored objects, occupy a large area or have a complicated structure. The repeater 1010 is installed in an appropriate number depending on the size of the building (10, 12, 14) and the number of the sensor 1002. In general, if the information transmission between the sensor 1002, the repeater 1010 and the remote controller 1004 is wireless, the installation is easy. However, depending on the structure and internal structure of the building (10, 12, 14), furniture facilities, etc. for the reasons of cost, such as the detection sensor n (1002.n), the repeater 1010 and the detection sensor n (1002). It may be desirable to provide wiring between n).

The remote controller 1004 primarily stores, processes, and transmits a detection signal and an identification symbol received from the detection sensor 1002 to the central control apparatus 200. The remote monitoring apparatus 100 is installed at a predetermined position of each building 10, 12, 14, and the installation position thereof depends on the type of communication network used (i.e., whether it is a wireless communication network or a wired communication network). Depending on the type and state of the (10, 12, 14) and the distribution of the detection sensor 1002, it is preferable to select a place where communication can be smooth and there is no fear of damage or failure.

As illustrated in FIG. 4, the remote controller 1004 includes a sensing information processing module 1006, a receiving module 1008, a transmitting module 1009, a transmission time determining module 1011, a memory 1012, and data input. The functional modules of module 1014 may be provided. First, let's briefly review the function of each module.

The receiving module 1008 receives a sensing signal and other information from the sensing sensor 1002 or the repeater 1010 and transmits the sensing signal and other information to the sensing information processing module 1006. The detection information processing module 1006 collects pest related information by processing the received detection signal. Pest related information includes information such as, for example, the type of pests infiltrated, the number of insect traps, the time of penetration, the path of penetration, the location of penetration, etc., and various information can be generated according to the type and arrangement of the sensor 1002. Do. The processed pest related information is transmitted to the transmitting module 1009, and the transmitting module 1009 transmits the processed pest related information to the central control apparatus 200. The transmission time determining module 1011 determines whether to transmit pest-related information to the central control apparatus 200 periodically or in real time. The memory 1012 may be used to store pest related information of a corresponding control target. The data input module 1014 is used when a control person manually inputs pest-related information that is not detected by the sensor 1002. Alternatively, it may be used to correct when there is an error in the data of the sensor 1002.

The remote controller 1004 will be described in more detail below.

The sensing information processing module 1006 of the remote controller 1004 processes the sensing signal transmitted from each of the sensing sensors 1002.1 and 1002.2 to 1002.n based on the identification code and the time information of the sensor transmitted together. When the detection information processing module 1006 does not receive any detection signal from the specific detection sensor 1002 for a long time or receives a value exceeding a predetermined range, the detection information processing module 1006 determines that the specific detection sensor 1002 is broken and detects the detection sensor 1002. Can output a sensor fault signal indicating that a fault has occurred. The sensing information processing module of the remote controller 1004 may convert the pest related information into a format suitable for transmitting to the central control apparatus 200.

The transmission module 1009 of the remote controller 1004 transmits the pest related information or the sensor failure signal to the central control apparatus 200 through the wireless communication network 300 or the wired communication network 400.

The transmission time determination module 1011 of the remote controller 1003 determines whether information transmission from the remote controller 1004 to the central control apparatus 200 will be performed regularly (for example, at a certain time of the night) or in real time. To judge. Whether to transmit regularly or in real time is preferably determined in consideration of the detected pest type, the type and state of the communication network used, and / or the type and state of the power source used by the remote controller 1004. In the case of using a general telephone network as the wired communication network 400, it is preferable to set the related information to be transmitted at night in order to minimize the disturbance of daily telephone calls. However, for example, when a high-hate creature such as a mouse emerges or when a pest appears at an abnormal frequency, the transmission time determination module 1011 of the remote controller 1004 may be set to immediately transmit information. . When the pest-related information is transmitted regularly, it is stored in the memory 1012 for a certain period of time. At this time, the storage space is divided into the memory 1012 to store the pest-related information for each time zone (for example, 0-8, 8-16, 16-24), or store information according to various other criteria. Can be.

The data input module 1014 of the remote controller 1004 may be used to input information that is difficult for the control person or the user of the monitored object to collect only by the sensor 1002 of the pest information. For example, if the control operation is performed only depending on the pest-related information obtained from the sensor 1002, the information of the area where the sensor 1002 is not installed can not be obtained. In addition, incorrect information accumulates due to a malfunction due to a simple defect, which may affect the reliability of the entire information. The data input module 1014 is to compensate for this point. When the user or the control person of the monitoring object inputs additional information to the data input module 1014, the information is aggregated by the sensor 1002. Likewise, it may be transmitted to the central control apparatus 200 via the transmission module 1009.

The functional modules 1006, 1008, 1009, 1012, 1014 of the remote controller 1004 described so far may be implemented as hardware individually designed to perform the above-described functions, and the above-mentioned functions may be programmed by programming general-purpose hardware. It may also be implemented as a software module that performs them.

Next, FIG. 5 is a block diagram conceptually illustrating a configuration of an embodiment of the central control apparatus 200 included in the remote monitoring system for control of FIG. 1.

As shown, the central control apparatus 200 receives the pest-related information transmitted in real time or periodically from the remote monitoring device 100 and the pest-related information analysis module 2002 for analyzing them, database the pest-related information Pest information management module (2006), database (2010) operated by pest information management module (2006), communication module (2012) for performing wired / wireless communication functions, and control operations are required. It includes a control time determination module 2014 for informing the time. Furthermore, the central control apparatus 200 may further include a report preparation module 2008 for preparing a report on a regular basis or when necessary with respect to the pest related information (report preparation module 2008 may be optionally included. It is indicated by a dotted line in Figure 5 to indicate that.).

The pest related information analysis module 2002 receives the pest related information from the communication module 2012 and analyzes the pest related information according to various categories. That is, according to the category (category), such as by location, date and time, by the type of pest and subdivision code installed in each area within the partitioned building, each building in which the remote monitoring device 100 is installed, Or according to various criteria that can be used for the control of pests, the analysis such that the information such as the frequency of appearance or infestation of pests, the appearance or infestation population can be identified.

For example, pest-related information classified according to subdivision codes can be used to establish control measures for specific monitored objects as follows. If there are multiple hypermarkets of similar structure to be monitored, these hypermarkets will consist of similar subdivisions. In this case, when pest-related information of subdivisions assigned the same subdivision code is compared between supermarkets, it is possible to determine where and what countermeasures should be taken by comparing the control status of each hypermarket. For example, the control person can use the relative value of each subdivision code to establish control measures, as well as the absolute number of pest outbreaks at each supermarket. For example, if the information on pests is not significantly different in the store subdivisions of two supermarkets A and B, but the warehouse subdivision shows that there is a much larger amount of pests, the pests in the store of supermarket A are relatively high. It may be determined that there are factors, and that additional control measures are required.

Meanwhile, in one embodiment of the present invention, the pest related information analysis module 2002 assigns a rating to each sensor 1002 in real time according to the number of infestations of pests detected by the sensor 1002. For example, in the case of 1 to 3 appearances L1 grade, 3 to 10 appearances L2 rating, 10-10 if the appearance of the L3 rating is given to each sensor 1002. When the number of detected pests increases, the class of the sensor 1002 is raised, and after the control operation is performed, the class of each sensor 1002 is reset. Thus, the grade given to each sensor 1002 can be usefully used to determine the appearance of pests and determine whether emergency measures such as dispatching are required immediately (details will be described later). The information analyzed in the information analysis module 2002 may include a history of pests in the past in each zone. With pest history information, control personnel can determine whether new pests have occurred, new pathways for existing pests have occurred, and whether the control agents used are effective. The category for analysis of pest-related information may be easily added or removed according to the needs of the user.

Next, the pest related information operation module 2006 stores the pest related information transmitted in real time or periodically from the remote monitoring apparatus 100 in the database 2010. That is, the pest related information operation module 2006 receives the pest related information newly transmitted from the remote monitoring apparatus 100 and adds or updates the existing information to the existing information. Various analysis categories used by the pest related information analysis module 2002 are also stored and managed in the database 2010.

The control time determination module 2014 determines whether the control operation is necessary immediately based on the analysis result of the pest related information analysis module 2002. The control time determination module 2014 reports an analysis result of the pest related information analysis module 2002 and if an emergency situation is determined, an alarm is notified to notify the control person.

Hereinafter, with reference to FIGS. 6 to 8, a specific example in which the control time determination module 2014 uses the result analyzed by the pest related information analysis module 2002 (hereinafter referred to as “analysis result”) will be described.

6 is a table showing the results of analysis on the activity of cockroaches in any one subdivision.

Referring to the table of FIG. 6, the number of cockroaches detected by each detection sensor 1002 and the grade given to each detection sensor 1002 for each of the 10 detection sensors 1002 installed in the subdivision area are shown as an analysis result. . In this subdivision, it is analyzed that there are three L1 level sensors (detecting 1 to 3 cockroaches) and 1 L2 level sensor (detecting 4 to 10 cockroaches). The analysis result of the data structure as shown for each type of pest in each subdivision is preferably provided by the pest related information analysis module 2002 in real time.

The control time determination module 2014 determines the control time using the analysis result as described above.

7A to 7C are examples of a table ("alarm table") used when the control time determination module 2014 determines the control time. The alarm table provided in the case of a rat in FIG. 7A, a cockroach in FIG. 7B, and a fly pest in FIG. 7C is taken as an example.

7A to 7C are tables showing which of A alarms, B alarms, and C alarms are determined according to the analysis results of FIG. 6, that is, the number of L1 and L2 sensors. The type of alarm here indicates the severity of the pest situation within the subdivision. In one embodiment of the present invention, if the A alarm means that the person in charge of the control should be careful when performing regular control work, and this means that if the B alarm or C alarm or more, the control work can be made immediately. In the case of an alarm, the control may be performed immediately. In the case of an alarm, the control may be performed immediately after a predetermined number of times.

For example, in the case of the rat, the alarm table (Table 1) of FIG. 7A shows a B alarm when 1 to 3 L1 level sensors 1002 are included in each subdivision area, and a L1 level sensor 1002. Is 4 or more, or if there is more than one detection sensor 1002 of the L2 rating means that the C alarm.

The type of alarm is determined in consideration of the type of pest and the subdivision in which the pest appears, and accordingly, the alarm table may vary according to the characteristics of the subdivision. For example, the three tables shown in FIG. 7B are for applying three different criteria depending on the subdivisions of the cockroach among pests. In the case of Table 1 of FIG. 7B, if there is only one detection sensor 1002 of L1 level, in the case of Table 3, if there is one detection sensor 1002 of L1 level, B alarm. In FIG. 7B, Table 1 applies to areas where pests are always generated, such as toilets and kitchens, and Table 3 may be applied to areas that have a serious effect when cockroaches emerge, such as a hotel room or a hospital room.

8 is an application table for determining which table should be applied according to the subdivision code (ie, the characteristics of the subdivision). These application tables may be updated to take into account whether they are specially controlled and subject to specificity of the subdivision. In the case of cockroaches as well as rats and non-fly pests, a variety of different alarm tables can be used.

Hereinafter, the information related to the appearance and pest frequency of the pests are analyzed by the pest related information analysis module 2002, and the analysis result as shown in FIG. 6 will be described in more detail. Surveillance will be limited to general rooms and toilets in Room 103 of A Hotel. In this case, the major category is Hotel A, the floor category is 10th floor, and the middle category is No. 1003. The subdivisions are general rooms and toilets.

When 14 cockroaches appear in the room 1003 and are detected by 4 out of 10 sensors 1002 installed in Hotel A / 10F / 1003 / room, the pest-related information is transmitted to the central control center. . After that, when the pest related information is analyzed by the pest related information analysis module 2002 for each location of appearance, the analysis result as shown in FIG. 6 is obtained for each sensor 1002 installed in Hotel A / 10F / 1003 / the general guest room. Lose. In this case, namely, when fourteen cockroaches appear in a general room, the four detection sensors 1002 detects one or three cockroaches by a pest related information analysis module 2002, and a detection sensor. 3 and 8 are given a L1 rating, and a detection sensor 7 that detects 4-10 cockroaches is given an L2 rating. Referring to the application table of FIG. 8, Table 3 of FIG. 7B applies to a general room. Therefore, in this case, that is, since there is one L2 grade sensor 1002 in the general room, the C alarm sounds, and the control person is immediately put in for the control operation.

If the analysis result shown in FIG. 6 relates to a cockroach that appeared in a bathroom rather than a general room, referring to the application table of FIG. 7, Table 1 of FIG. 7B is applied. Therefore, unlike the general room, the alarm A sounds. In the case of alarm A, the control action does not need to be performed immediately, but means that the control action should be performed during regular work.

However, no matter how many pests are in the toilet, if you frequently come in need immediate control. In this case, the control time determination module 2014 uses the information analyzed for each appearance frequency. For example, if it is analyzed that the detection sensor 1002 of the L1 grade three or more times a week, the control period determination module 2014 may be set to sound the B alarm. As described above, not only the alarm table shown in FIG. 7 but also the alarm table based on various criteria and applied to the corresponding pest-related information, it is possible to ensure the occurrence of pests.

Next, the communication module 2012 included in the central control apparatus 200 performs a wired or wireless communication function with the communication module 1008 included in the remote sensing device 100. Technical details necessary for wired and wireless communication are already well known, and thus detailed descriptions are omitted.

9A and 9B, a report generation module 2008 that may be selectively included in the central control apparatus 200 will be described in detail. 9A and 9B illustrate an embodiment of a report generated by the report preparation module 2008 of the central control apparatus 200.

As shown in FIG. 9A, the report preparation module 2008 may generate a report of the pest related information of the day at a predetermined time every day based on the analysis result of the pest related information analysis module 2002. The report according to the present embodiment includes the number of pests detected for each time zone (eg, time zone 1, time zone 2, time zone 3, etc.) and for each building 10, 12, 14. In the remote monitoring apparatus 100 or the central control apparatus 200, such a report can be easily generated by classifying and storing pest related information by time zone, building, and the like. The activity population for each building (10, 12, 14) is again divided by the location where the sensor 1002 is installed, the number of pests detected as being captured at each installation location is recorded separately by their type.

9B is one embodiment of a report (hereinafter referred to as "zone report") that records information about a zone of a partitioned monitored object. As a zone report of the production building of FIG. 3, the case where it divided into four steps is shown.

These zone reports are stored in advance in the central control unit 200 so that the control personnel can easily perform the control operation according to each zone of the monitoring target. Zone reports may be updated after each response. The zone report of FIG. 9B includes the names of each zone partitioned, a description of the location of each zone, a subdivision code for each zone, information about the number of installation equipment installed in each subdivision zone, and whether the zone is vulnerable. The second and third columns show the major classification, floor classification, middle classification, and subdivision of each zone, and the location description column briefly describes the location of each subdivision. In the Subdivision Code field, the subdivision code corresponding to each subdivision is entered. In the present embodiment, it can be seen that the production section and the storage section are given the same subdivision code, and thus the same kind of control equipment is installed. In the Installation Equipment / Number column, the equipment installed in the subdivision area and the number of them are listed. The Vulnerable Areas column indicates cases where the frequency of appearance of pests is higher than the prescribed number, or where it is determined to be vulnerable to pests for other reasons. By reviewing these reports, the control personnel can see at a glance the composition of the monitored object, and when used in conjunction with a pest-related information report, they can identify the situation of pests in each area at a glance. Such reports make it easier for the control personnel to identify the information they need without relying on individual memories or experiences. Therefore, even if the control personnel of the control target building is changed, it is always possible to control in an efficient manner, and ultimately anyone can perform efficient control if a personnel with predetermined control capabilities are dispatched without a dedicated control personnel. In the present specification, the report does not mean only a form actually printed on paper, but may include a form displayed on a screen, an electronic file, an e-mail, and the like.

In the case of using such a report, it is systematically delivered to the control person of the pest-related information obtained from the sensor 1002 installed in each zone by compartmentalization, and the manager can review the information of each compartment at a glance and work on the control.

Such a report is preferably generated by using the analysis result of the pest related information analysis module 2002, and the report on the pest related information may be generated regularly or as necessary, as described above. In addition, such reports can be accumulated over a period of time and statistically reanalyzed and used according to a defined category. In other words, a report written for a relatively short unit of time can be accumulated over a long period of time (months, seasons, years) to observe its trends and to find secondary information related to control. For example, if the pest information increased gradually over a long period of time in a control building where similar information was shown for a long time, there was a factor that affected the pest, although it was not a big factor. It can be inferred. In addition, such long-term analysis can be used to identify the effects of changes in the structure of buildings and control agents on pest activity. In order to observe such long-term trends, pest-related information analyzed for a short period of time can be sampled or used on an average of weeks or months.

The pest-related information can be analyzed according to a predetermined category, and as a result, the location of the drug that can eradicate the species of a particular pest and the requirements of the drug can be determined and included in the report. In this case, the control person can install the medicine in the building to be controlled based on this report, thereby reducing the hassle of confirming the location and amount of the medicine. In this case, the position and the amount of the drug may be determined by using a simple arithmetic expression or by referring to a lookup table according to the pest related information (or secondary information from which the information is analyzed) in the detection sensor 1002.

In addition, in one embodiment of the present invention it is possible to prepare a report containing the activity information of the pest to be eliminated by the drug at the installation location before and after the installation of the drug, this report is a graph that is easy to observe the trend It can be written in a format. Such a report can be used to observe the effects of drug installation on the pest and, if there is no impact, to determine that drug resistance has occurred in the pest in the area.

Using these zone reports, it is possible to efficiently manage the location of the sensor 1002 and the control equipment installed in each zone. The zone report described above shows the type and number of control equipment installed in each zone. Therefore, the control person checks the number of control equipment installed in each zone at the time of the control operation, take appropriate measures such as removing captured pests and checking their function.

Next, with reference to Figures 10 and 11 will be described in detail the operation of the remote monitoring system for control according to an embodiment of the present invention.

First, the main operation of the remote monitoring apparatus 100 will be described with reference to FIG. 10. FIG. 10 is a flowchart conceptually illustrating a main operation of the remote monitoring apparatus 100 of the remote monitoring system for controlling of FIG. 1.

As shown, once power is input and operation begins (step 600), components such as remote controller 1004 and sensor 1002 are checked (steps 604 and 606). As a result of the check, the statuses of the remote controller 1004 and the detection sensor 1002 are transmitted and reported to the central control apparatus 200 (step 608). Through the status reporting step, the central control apparatus 200 prepares to perform communication with the corresponding remote controller in the future. This status report is preferably performed periodically, as well as at the time of power input, so as to periodically check the status of the remote monitoring apparatus 100 in the central control center.

Next, the remote monitoring apparatus 100 collects pest related information by receiving a detection signal from each sensor 1002 (step 610), and transmits the collected pest related information to the central control apparatus 200. (Step 612).

Control of the operation of the remote monitoring apparatus 100 is then returned to the appropriate one of the above steps (step 614). The steps are not necessarily performed sequentially, and not all steps have to be repeated the same number of times until after power is released.

Next, a main operation of the central control apparatus 200 will be described with reference to FIG. 11. FIG. 11 is a flowchart conceptually illustrating a main operation of the central control apparatus 200 of the remote monitoring system for control of FIG. 1.

As shown, power is first applied and operation begins (step 500). The central control apparatus 200 receives a status report indicating whether the remote controller 1004 and the sensor 1002 are operating normally from the remote monitoring apparatus 100 (step 502) and then determines whether there is an abnormality (step 503). do. As a result of the check, if the components of the remote monitoring apparatus 100 are normally operated, the process proceeds to the next step. However, if it is confirmed that the state of the sensor 1002 or the remote controller 1004 of the remote monitoring apparatus 100 is abnormal (step 504). The control person, for example, if it is determined that the detection sensor 1002 in a critical area, such as a hotel room is broken, immediately go to the monitoring object and repair it, and in the case of the same area as the bathroom to repair it during regular work. In order to obtain a reliable response, if a response indicating that it is operating abnormally is received several times, for example, three times, it may be set to report an abnormality of the remote monitoring apparatus 100 after receiving a status report.

Next, the pest related information transmitted from the remote monitoring apparatus 100 is received (step 506). For normal reception of pest related information, an operation such as checking the communication module 2012 to confirm that it is normal should be performed first, but since these operations are obvious to those skilled in the art of the present invention, the details thereof will be described. It will be omitted.

Next, the central control apparatus 200 compares the received pest-related information with the pest-related information previously stored in its database 2010 and updates the ones to be updated and stores the ones to be newly stored. Perform step 508.

Next, the pest-related information stored or updated in the database is analyzed based on a predetermined analysis category (step 510). As described above, the analysis of the pest-related information is various, such as by the building in which the remote monitoring device 100 is installed, by the location where the detection sensor 1002 is installed in each building, by the time zone of a specific date, and by the type of pest to be controlled. Based on the category, it is desirable to analyze the information such as the frequency of infestation or infestation of pests, the appearance or infestation population, and the like.

Next, as an operation that can be selectively performed, the central control apparatus 200 may create a report for reporting the analysis result of the pest related information (step 512). The report has been described in detail with reference to FIGS. 9A and 9B and thus will be omitted. In addition, the analysis result or report of the pest-related information may be transmitted again to the user of each building (10, 12, 14) or the control person (step 514). Step 514 may optionally also be performed.

Control of the operation of the central control apparatus 200 is then returned to the appropriate one of the above-described steps (step 516).

The steps are not necessarily performed sequentially, and not all steps have to be repeated the same number of times until after power is released.

Hereinafter, another embodiment of the present invention will be described.

12 is a block diagram conceptually showing a configuration of a remote monitoring system for control according to a second embodiment of the present invention. The same components as those in FIG. 1 are shown using the same reference numerals.

The second embodiment of the present invention differs from the first embodiment in that the central control apparatus 200 transmits the analysis result of the pest related information to the user of each building 10, 12, 14 or the control person in charge. will be. In particular, the control person receives the analysis result of the pest-related information using a portable communication terminal 70, such as a personal data assistance (PDA) or a mobile phone, and accordingly each building (10, 12, 14) You can carry out appropriate control activities.

13 is a block diagram conceptually showing a central control apparatus 200 according to a second embodiment of the present invention.

In the second embodiment of the present invention, the receiving module 900 and the transmitting module 910 are provided in place of the communication module of the first embodiment. In addition, it may optionally include a location search module 920.

In the second embodiment, the reception module 900 receives the pest related information from the remote monitoring device 100 and transmits the pest related information to the pest related information analysis module 2002. The analysis result of the pest related information is transmitted by the transmission module 910 of the central control apparatus 200 to the portable communication terminal 70 possessed by the person in charge of controlling the buildings 10, 12, 14 associated with the information. Control personnel may be sent regularly to transmit pest-related information for their buildings, and may be sent at the request of the control personnel or by other predetermined criteria. For example, when a schedule of dispatching a control person directly to a control target building is transmitted in advance, according to the schedule, pest-related information of a target building to be visited on the day may be transmitted to the portable communication terminal 70 of the person in charge. In one embodiment of the present invention, when an emergency situation occurs in the control target building, the central control apparatus 200 after searching the location of the control personnel carrying the portable communication terminal 70 by the location search module 920 Pest-related information may be sent to the control personnel closest to the building in which the emergency occurred. The location search module 920 may be provided with location information whenever necessary in association with a mobile communication service provider capable of searching for a location of the portable communication terminal 70 using a GPS (Global Positioning System).

In addition, when using the portable communication terminal 70 and the location search module 920, as in the embodiment of the present invention, it is possible to effectively manage the movement paths of the several control personnel. For example, since the position of each control person can be grasped | ascertained by the central control center through the portable communication terminal 70, the order of a control operation can be determined efficiently. If the order of response of each person in charge is prioritized, the priority is given to the monitoring objects located in the shortest travel distance or the route that takes less time according to the traffic situation. The efficiency can be improved.

According to the second embodiment of the present invention, it is possible to shorten the time taken until the control operation after the emergence of the emergency by the pest. Typically, since the plurality of remote monitoring apparatuses 100 are connected to one central monitoring apparatus 200 by wire or wirelessly, the specific remote monitoring apparatus 100 may be located far away from the central monitoring apparatus 200. After the pest-related information is analyzed in the central control apparatus 200, the control personnel in the central control center to see the result of the analysis and go to the remote building, it takes a considerable time in the meantime. If a mouse emerges, the mouse generates a great aversion, so it is important to eradicate it urgently. Therefore, in this case, according to the second embodiment of the present invention, the control person in the vicinity of the building in which the rat has been haunted is automatically contacted, so that the rat can be quickly eradicated. In addition, other pest-related information of the building can be reviewed during the dispatch by the person in charge, so you can go to exterminate the rats and perform other regular inspection and control work.

14 is a block diagram conceptually showing the configuration of a remote monitoring system for control according to a third embodiment of the present invention. The same components as those in FIG. 1 are shown using the same reference numerals.

The third embodiment of the present invention differs from the second embodiment in that the transmission of pest related information to the portable communication terminal 70 may be made directly from the remote monitoring apparatus 100 to the portable communication terminal 70. In FIG. 14, the portable communication terminal 70 wirelessly communicates with the remote monitoring apparatus 100, but both wired and wireless communication may be enabled. In the third embodiment, the control person may receive instructions from the remote monitoring device 100 or the central control device 200 of the building, and the pest-related information may be received from both of them. .

15 is a block diagram conceptually showing a remote monitoring apparatus 100 according to a third embodiment of the present invention.

In comparison with the first embodiment, a pest related information analysis module 1018, a pest related information operating module 1022 and a terminal connection module 1016 have been added to the remote controller 1004. In addition, the location search module 1020 may optionally be added.

The position search module 1020 is installed in the remote controller 1004 to search for the position of the portable communication terminal 70. The detailed information analysis is performed by the pest related information analysis module 1018 of the remote monitoring apparatus 100. The process of analyzing the pest related information in the pest related information analysis module 1018 is the same as in the central control apparatus 200. The analysis result is stored in the memory 1012 by the pest related information operating module 1022. The control person who receives the dispatch instruction by the pest to the portable communication terminal 70 goes to the control target building and connects the portable communication terminal 70 to the terminal connection module 1016 of the remote controller 1004 by wire or wirelessly. . When the portable communication terminal 70 is connected to the terminal connection module 1016, the terminal connection module 1016 reads the analysis result of the pest related information stored in the memory 1012 and transmits the result to the portable communication terminal 70. The control person who receives the analysis result of the pest related information into the portable communication terminal 70 performs a control operation based on this. Although not shown in the figure, the remote controller 1004 according to the third embodiment may also transmit a report, including the report generation module, to the portable communication terminal 70 through the terminal connection module 1018. For example, after confirming on the screen a report containing information about the area of the building to be controlled, the control person can start the control work appropriate to the structure of the building.

In the third embodiment, a large portion of information that the portable communication terminal 70 needs to receive may be transmitted directly from the remote monitoring apparatus 100 to the portable communication terminal 70 without using a conventional commercial wireless communication system. Therefore, the cost associated with wireless data transmission can be reduced.

Also in the third embodiment, like the second embodiment, the position search module 1002 can be used for the position search of the control person closest to the monitoring object. In addition, when emergency dispatch is required, dispatch instruction can be made to the portable communication terminal 70 of the control person in the closest position from the remote monitoring apparatus 100.

In the above, the case in which the analysis of the pest related information is performed in the remote controller 1004 has been described. Can be implemented by adding That is, the portable communication terminal 70 may include a pest related information analysis module. The process of processing pest related information in the portable communication terminal 70 is the same as in the central control apparatus 200.

According to the second and third embodiments of the present invention, it is possible for the control person closest to the monitoring object to perform the control operation. Conventionally, a control person is determined for each monitoring object, and only a corresponding control person has performed control work. If the control personnel of the monitored object suddenly changed, efficient control work could not be achieved because the new control personnel did not have systematic information on the monitored object. However, in the second and third embodiments of the present invention, the control person is dispatched the analyzed pest related information for each zone partitioned from the central control apparatus 200 or the remote controller 100 to the control target building. Since it is possible to obtain even, any control personnel can be dispatched to efficiently control the control of the target building.

While many details are set forth in the foregoing description, it should be construed as an illustration of preferred embodiments rather than to limit the scope of the invention. Therefore, the scope of the invention should not be defined by the described embodiments, but should be defined by the claims and the equivalents of the claims.

According to the remote monitoring system for control of the present invention and the method, it is possible to grasp and analyze the information on the ecology of the pest by various categories.

In addition, according to the remote monitoring system for control and the method of the present invention, it is possible to centralize and centralize the information on the ecology of the pest collected by each building in the central control center.

In addition, according to the remote monitoring system and method for controlling the present invention, it is possible to perform effective control activities by collecting and managing information on the ecology of the pest.

In addition, according to the remote monitoring system and method for controlling the present invention, infestation or activity of pests are counted in real time by using a sensor, and using this data to prepare a recurrence prevention plan through data aggregation and analysis, as well as nationwide Precautionary measures are possible by conducting surveys of occurrence distribution and seasonal distribution, and by knowing and dealing with the exact place of inflow, timing of inflow, and number of occurrences, it is indiscriminate drug abuse, personnel, and time-saving economics. There is an effect that can prevent the loss in advance.

In addition, according to the present invention, it is possible to easily grasp the information required by the control personnel without relying on the memory and experience of the individual control personnel. Therefore, even if the control person in charge is changed, control can always be carried out in an efficient manner.

In addition, it is possible to ensure that pest control information is always provided to the control personnel, it is possible to reduce the travel time by managing the movement of the control personnel.

Claims (37)

At least one detection sensor installed in a plurality of partitioned areas of the monitoring object to detect a movement of a pest in each zone and to generate and transmit a detection signal according to the detection; At least one remote controller installed in the monitoring object and configured to receive the detection signal and process and transmit the received detection signal; And Central control device for receiving information transmitted from the remote controller to analyze and operate for each zone Control remote monitoring system comprising a. The remote monitoring system of claim 1, further comprising at least one repeater installed in the monitoring object and receiving the detection signal from the detection sensor and retransmitting to the remote controller. The remote monitoring system for controlling pests according to claim 1, wherein the detection signal is transmitted between the detection sensor and the remote controller. The remote monitoring system of claim 2, wherein transmission and retransmission of a detection signal between the detection sensor, the repeater, and the remote controller is performed wirelessly. The remote monitoring system of claim 2, wherein transmission of the detection signal between the detection sensor and the relay period is performed by wire, and retransmission of the detection signal between the relay and the remote controller is performed wirelessly. The method of claim 1, wherein the detection sensor, A first sensor for detecting a movement of a cockroach; A second sensor for detecting the movement of the rat; And Third sensor for detecting the movement of insect pests Remote monitoring system for control comprising at least any one. The method of claim 1, wherein the detection sensor, Remote monitoring system for control installed with control equipment to capture pests. The method of claim 1, wherein the detection sensor, Remote monitoring system implemented by adding a heat sensor or motion detector to a selected one from manned insects, automatic pharmaceutical spraying device, and rodent manned capture frame. The method of claim 1, wherein the remote controller, A receiving module for receiving a detection signal from the detection sensor; A sensing information processing module which receives the sensing signal from the receiving module and processes the sensing signal to collect the pest related information; And Transmission module for transmitting the processed pest related information to the central control device Control remote monitoring system comprising a. 10. The method of claim 9, wherein the remote controller, Remote monitoring system for control further comprising a data input module for manually inputting information on the occurrence of pests from the user or control personnel of the monitoring object. 10. The method of claim 9, wherein the remote controller, A transmission time determining module that determines whether to immediately transmit the pest related information; And A memory for storing a result of processing the pest related information for a predetermined period until the pest related information is transmitted if the transmission time determining module determines that the pest related information is not immediately transmitted. Remote monitoring system for controlling pests further comprising. According to claim 1, wherein the central control device, A pest related information analysis module configured to receive pest related information transmitted from the remote monitoring apparatus and analyze the information by zones; A pest related information operation module configured to store, update, and operate a pest related information transmitted from the remote monitoring apparatus as a database; A database operated by the pest related information operation module; A control time determination module that determines whether to execute a control operation immediately based on the information analyzed by the pest related information analysis module; And Communication module to perform wired and wireless communication functions Control remote monitoring system comprising a. The method of claim 12, wherein the central control device, Remote control system for control further comprising a report generation module for creating a report with respect to the pest related information. The method of claim 1, wherein the detection sensor, Generating a detection signal in response to the detection of the pest, wherein the generated detection signal is transmitted together with an identification symbol of each detection sensor. The remote monitoring system for controlling pests according to claim 1, wherein the remote controller transmits the pest related information to a central control apparatus using a general telephone network. The method of claim 12, wherein the central control device, It further comprises a location search module for searching for the location of the portable communication terminal to search for the location of the control personnel carrying a portable communication terminal, And the communication module transmits analysis information of pest related information to the portable communication terminal searched by the location search module. 10. The method of claim 9, wherein the remote controller, A pest related information analysis module configured to receive and analyze pest related information received from the sensing information processing module; A pest related information operation module configured to store and update the result analyzed by the pest related information analysis module in the memory; And When the portable communication terminal is connected, the terminal connection module for transmitting the analysis result of the pest-related information from the memory to the portable communication terminal Remote monitoring system for controlling further comprising. The remote monitoring system for control according to claim 16 or 17, wherein the portable communication terminal is a PDA. The method according to claim 12, wherein the related information analysis module classifies each detection sensor according to the detected number of pests, The control period determination module for controlling the remote monitoring system for determining the control time of the zone based on the level of the sensor in each zone. The method of claim 11, wherein the transmission time determination module, When the cockroach or fly pests are detected, the pest-related information is transmitted at a predetermined time, and if a mouse is detected, the remote monitoring system for the control immediately transmits the pest-related information. The method of claim 1, wherein the sensor and the remote controller, A remote monitoring system for control that periodically checks the status including the presence of a failure and transmits the information to the central control unit. Partitioning the monitored object into a plurality of zones; Detecting pests active in each compartment and collecting related information; Transmitting the collected pest related information to the central control apparatus; Analyzing the transmitted pest related information; Updating and storing the analyzed pest related information in comparison with information previously stored in a database; And Determining a control time based on the analyzed pest related information Remote monitoring method for a control comprising a. 23. The method of claim 22, further comprising the step of creating a report using the analyzed pest related information. The method of claim 22, wherein the partitioning step, Remote monitoring method for the control to divide the monitored object into a physical area. The method of claim 22, wherein the partitioning step, The remote monitoring method for control which divides each area | region in the said monitoring object according to the function. The method of claim 24 or 25, wherein the partitioning step, Remote monitoring method for the control to divide each area in the monitoring object to the minimum unit that the control is made. The method of claim 24, wherein the partitioning step, Dividing the monitoring object into each building and its surroundings; And Partitioning the building into each floor Remote monitoring method for a control comprising a. 27. The system of claim 26, wherein a code is assigned to each area of the minimum unit, Analyzing the pest related information comprises the step of arranging the pest-related information for each code for each area partitioned of the plurality of monitoring targets. 23. The method of claim 22, wherein the pest related information is transmitted at a preset time. The method of claim 22, wherein the pest related information, Remote monitoring method that is transmitted when a cockroach or fly pest is detected at a preset time and immediately when a rat is detected. 30. The method of claim 28 or 29, wherein the preset time is night. 23. The method of claim 22, further comprising wirelessly transmitting the analyzed pest related information to at least one control person. The method of claim 22, wherein analyzing the pest related information comprises: Remote control method for controlling the control of the number of pests infestation or capture according to the category by location, the specific time zone and the type of pests to be controlled. 23. The method of claim 22, further comprising transmitting the analyzed pest-related information to a portable communication terminal possessed by the control person. 34. The method for controlling remote monitoring according to claim 33, wherein shortest path information to the monitored object is transmitted together with the analyzed pest related information. 23. The method of claim 22, further comprising: retrieving the location of the response personnel; And Transmitting the analyzed pest related information to a portable communication terminal possessed by the control person; Remote monitoring method for the control further comprising. 23. The method of claim 22, further comprising transmitting the collected pest-related information to a portable communication terminal possessed by a control person.