KR100954389B1 - System for controlling data communication and method for processing data using the same - Google Patents

Abstract

A data communication control system and a method for processing data using the data communication control system are provided. The data communication control system of the present invention includes a first sensor for generating sensing data; A data collector configured to bidirectionally communicate with the first sensor using a first communication method, and receive and store the sensing data from the first sensor through the first communication method; And a central server which bidirectionally communicates with the data collector using a second communication scheme, receives the sensing data from the data collector through the second communication scheme, and analyzes and processes the data based on a predetermined condition. The central server may control an operation setting of the first sensor and the data collector.

Data communication, communication method, two way communication, level, operation setting, sensing data

Description

Data communication control system and data processing method using the same {SYSTEM FOR CONTROLLING DATA COMMUNICATION AND METHOD FOR PROCESSING DATA USING THE SAME}

The present invention relates to a data communication control system and a method for processing data using the data communication control system.

Communication means the exchange of information through means or media over a distance. The method of communication shows a lot of difference between before and after the development of electricity. Before the development, it was possible to communicate with a limited number of thoughts such as rupture, beacon and drum sound. Through mobile communication, satellite communication, etc., my information is delivered to the other party.

In addition, in the early stage of communication, voice-oriented information was added, but now data information (text, sound, image, etc.) has been added, and a large amount of transmission is required, and the media, exchange devices, and terminal devices for transmission have been greatly improved. New concepts of communication are emerging.

On the other hand, as the economy develops, living standards gradually improve, and pests that have been inadvertently obsolete in the past are now becoming a strong target for all. However, due to industrialization or industrialization, a large amount of waste is generated, and accordingly, pests are increasing.

The pest is a concept that collectively refers to insects or animals that harm humans and livestock, and these pests eat food or textiles, causing considerable damage to life, and excretion carry harmful pathogens to the human body. In recent years, such pests are increasing due to the polluted environment, the pest removal is a big problem.

However, conventionally, in the case of capturing pests, a pest control device is installed, and when the pests are captured in the pest control system, the captured pests are eliminated. However, in the past, pest capture information could not be obtained from a remote location, and the pest capture information could only be obtained after a person directly accesses and verifies the pest control periodically.

Accordingly, there is an urgent need for the development of a system capable of acquiring, analyzing and processing pest capture information in real time from a remote site without a person directly approaching the pest control device.

The present invention has been made to improve the prior art as described above, the present invention is a data communication control system capable of automatically obtaining information in real time from a server in real time through each node to which various communication schemes are applied and using the same It is an object to provide a data processing method.

Another object of the present invention is to provide a data communication control system capable of analyzing, processing and monitoring information obtained in real time and a data processing method using the same.

It is still another object of the present invention to provide a data communication control system and a data processing method using the same, by which an operation can be instructed based on a monitoring result, so that the operation can be performed quickly.

Still another object of the present invention is to provide a data communication control system and a data processing method using the same, which can notify a customer of a result of performing a task in real time by transmitting a result of performing a task to a customer terminal.

Another object of the present invention can be connected to a large number of sensors using the sensor expansion module, through which the data communication control system and data using the same can be installed in many places to obtain more accurate and reliable sensing information It is to provide a treatment method.

Still another object of the present invention is to provide a data communication control system and a data processing method using the same, which can quickly and accurately obtain sensing information from a large-scale workplace using a network expansion module.

The object of the present invention is not limited to the above-mentioned objects, and other objects not mentioned will be clearly understood by those skilled in the art from the following description.

In order to achieve the above object and solve the problems of the prior art, a data communication control system according to an aspect of the present invention, the communication control system, the first sensor for generating sensing data; A data collector configured to bidirectionally communicate with the first sensor using a first communication method, and receive and store the sensing data from the first sensor through the first communication method; And a central server which bidirectionally communicates with the data collector using a second communication scheme, receives the sensing data from the data collector through the second communication scheme, and analyzes and processes the data based on a predetermined condition. The central server controls the operation settings of the first sensor and the data collector.

In a data processing method using a data communication system according to another aspect of the present invention, in the method of processing data using a data communication control system, sensing data generated by a sensor is generated using a first communication method. Receiving and storing sensing data; And receiving the stored sensing data using a second communication scheme, and analyzing and processing the received sensing data based on a predetermined condition.

Specific details of other embodiments are included in the detailed description and the accompanying drawings.

Advantages and features of the present invention and methods for achieving them will be apparent with reference to the embodiments described below in detail with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but may be implemented in various different forms, only the present embodiments to make the disclosure of the present invention complete, and common knowledge in the art to which the present invention pertains. It is provided to fully inform the person having the scope of the invention, which is defined only by the scope of the claims. Like reference numerals refer to like elements throughout.

According to the present invention, it is possible to automatically obtain information at a remote location from a server in real time through each node to which various communication schemes are applied.

According to the present invention, it is possible to analyze, process and monitor the information obtained in real time.

According to the present invention, by instructing the operation based on the monitoring result, it is possible to perform the operation quickly.

According to the present invention, by transmitting the result of performing the work to the customer terminal, it is possible to inform the customer of the result of the work in real time.

According to the present invention, it is possible to connect a large number of sensors using the sensor expansion module, through which the sensor can be installed in many places to obtain more accurate and reliable sensing information.

According to the present invention, sensing information can be quickly and accurately obtained without difficulty by using a network expansion module.

Hereinafter, with reference to the accompanying drawings will be described in detail a data communication control system and method according to an embodiment of the present invention.

1 is a conceptual diagram of a data communication control system according to an embodiment of the present invention.

Referring to FIG. 1, a data communication control system according to an embodiment of the present invention includes a first sensor 110, a second sensor 120, a data collector 130, and a server 140.

The first sensor 110 may detect an object (including a cockroach, a mouse, a worm, an intruder, etc.) and generate sensing data corresponding thereto. The first sensor 110 may be installed in a customer's house or company. The first sensor 110 may include a pest control sensor. The pest control sensor may include a wheel trap, a rat feeder, or a reptile.

When the pest control sensor is a wheel trap, the first sensor 110 may generate pest-related information including sensing information of the cockroach, capture information of the cockroach, capture number information of the cockroach, and the like as the sensing data. Alternatively, when the pest control sensor is a mouse feed box, the first sensor 110 generates pest-related information including the appearance information of the rat, the capture information of the mouse, or the capture number information of the mouse as the sensing data. can do. In addition, when the pest control sensor is a reptile, the first sensor 110 may be used to capture information such as non-native pests (flies, fly flies, mosquitoes, etc.), ticks, or ants, capture information, or capture count information. Pest related information to be included may be generated as the sensing data.

In addition, the first sensor 110 may include a security sensor. The security sensor may include a smoke / gas sensor, a fire sensor, an infrared sensor, a camera, a motion detection sensor, a door open / close sensor, an impact sensor, or a pyroelectric sensor.

When the security sensor is a smoke / gas sensor, the first sensor 110 may generate security / safety related information including smoke / gas generation information as the sensing data. Alternatively, when the security sensor is a fire sensor, the first sensor 110 may generate security / safety related information including fire occurrence information as the sensing data. Alternatively, when the security sensor is at least one of an infrared sensor, a camera, a motion sensor, a door open sensor, an impact sensor, or a pyroelectric sensor, the first sensor 110 may be related to security / safety including intruder information. Information may be generated as the sensing data.

In addition, the first sensor 110 may include an environmental hygiene sensor. The environmental hygiene sensor may include a carbon dioxide sensor, a VOC sensor, a temperature sensor, a humidity sensor, a dust sensor, a gas sensor, a power sensor, or a water sensor.

When the environmental hygiene sensor is the carbon dioxide detection sensor, the first sensor 110 may generate environment / hygiene related information including carbon dioxide detection amount information as the sensing data. Alternatively, when the environmental hygiene sensor is a VOC sensor, the first sensor 110 uses environmental / hygiene related information including sensing amount of organic volatile matter such as aldehyde, fatty acid, and methane gas as the sensing data. Can be generated.

Alternatively, when the environmental hygiene sensor is the temperature sensor, the first sensor 110 may generate environment / hygiene related information including temperature information as the sensing data. Alternatively, when the environmental hygiene sensor is the humidity sensor, the first sensor 110 may generate environment / hygiene related information including humidity information as the sensing data. Alternatively, when the environmental hygiene sensor is the dust sensor, the first sensor 110 may generate environment / hygiene related information including dust sensing amount information as the sensing data.

Alternatively, when the environmental hygiene sensor is the gas sensor, the first sensor 110 may generate environment / hygiene related information including gas leakage amount information as the sensing data. Alternatively, when the environmental hygiene sensor is the power sensor, the first sensor 110 may generate environment / hygiene related information including power usage or leakage information as the sensing data. Alternatively, when the environmental hygiene sensor is the water sensor, the first sensor 110 may generate environment / hygiene related information including water freezing wave information or water leakage information as the sensing data.

The second sensor 120 bidirectionally communicates with the first sensor 110 using the first communication method, and receives the sensing data from the first sensor 110 through the first communication method. Here, the first communication scheme may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485.

The second sensor 120 bidirectionally communicates with the data collector 130 by using a third communication method, and transmits the sensing data to the data collector 130 through the third communication method. Here, the third communication method may include a ZigBee protocol.

The second sensor 120 may include a sensor expansion module. The sensor expansion module may expand by adding a connection number of the first sensor 110. That is, the sensor expansion module is a module for increasing the number of connections of the first sensor 110 connected to the second sensor 120. For example, the first sensor 110 is connected to one second sensor 120. ) Can be connected up to 200.

The second sensor 120 may further include a router module. The router module may route and address the first sensor 110. That is, when the router module sends data (packets) to the first sensor 110, the router module searches for an address of the first sensor 110, which is a destination to receive the data, and transmits the data in the shortest (or optimal) path. Send to sensor 110. The second sensor 120 may be installed in a customer's house or company.

Meanwhile, like the first sensor 110, the second sensor 120 may detect an object (including a cockroach, a mouse, a worm, an intruder, etc.) and generate sensing data corresponding thereto. In this case, the second sensor 120 may be implemented as a pest control sensor, a security sensor, an environmental hygiene sensor, and the like as the first sensor 110.

The data collector 130 may bidirectionally communicate with the first sensor 110 using a first communication method, and receive and store the sensing data from the first sensor 110 through the first communication method. Here, the first communication scheme may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485 as mentioned above.

The data collector 130 bidirectionally communicates with the second sensor 120 using the third communication method, and the server 140 receives the sensing data received and stored from the second sensor 120 through the third communication method. To send). Here, the third communication method may include a ZigBee protocol as described above.

The data collector 130 may process the sensing data according to an operation set by the server 140. That is, the data collector 130 may transmit the sensing data to the server 140 according to the data transmission period information set by the server 140. Alternatively, the data collector 130 may transmit the sensing data to the server 140 according to data accumulation amount information capable of data transmission set by the server 140.

For example, when the data transmission period information is one hour by the server 140, the data collector 130 may transmit the sensing data to the server 140 at a period of one hour. As another example, when the data accumulation amount information that can be transmitted by the server 140 is 1MB, the data collector 130 transfers the sensing data to the server 140 when the data accumulation amount information reaches or exceeds 1MB. Can transmit

The server 140 bidirectionally communicates with the data collector 130 using a second communication method, and receives the sensing data from the data collector 130 through the second communication method based on a predetermined condition. Can be processed. Here, the selected condition may include level information for each sensing data or level information for each zone. In addition, the second communication scheme may include Code Division Multiple Access (CDMA), Ethernet, Internet, or Public Switched Telephone Network (PSTN).

When the selected condition is level information for each sensing data, the server 140 may classify and analyze and process the sensing data based on the level information for each sensing data. That is, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority.

For example, when the sensing data is the pest-related information, it is assumed that the level information for each sensing data is rat (level 1), cockroach (level 2), ant (level 3), or fly (level 4). In this case, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority. That is, the server 140 determines the priority in order of rat-> cockroach-> ant-> fly using the level information for each sensing data, and according to the determined priority, the sensing data (rat, cockroach, ant, Appearance information, capture information, capture number information, etc. of each fly can be analyzed and processed.

When the selected condition is level information for each zone, the server 140 may classify and analyze and process the sensing data based on the level information for each zone. That is, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. In this case, it is assumed that the first sensor 110 is distributed and installed in each area (place). For example, the first sensor 110 may be distributed and installed in a production line, a raw material warehouse, an office, and the like.

For example, when the sensing data is the pest related information, it is assumed that the level information for each zone is a raw material warehouse (level 1), a production line (level 2), and an office (level 3). In this case, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. That is, the server 140 determines the priority in order of the raw material warehouse-> production line-> office using the level information for each zone, and the sensing data (rat, cockroach, ant, flies, respectively) according to the determined priority. Information, capture information, or capture count information) may be analyzed and processed.

The server 140 may control operation settings of the first sensor 110, the second sensor 120, and the data collector 130. Here, the operation setting may include sensing period information, level information for each sensing data, level information for each region, data transmission period information, or data accumulation amount information for data transmission.

In other words, the server 140 may set and apply sensing period information, data transmission period information, and the like to the first sensor 110 or the second sensor 120, and the sensing data level may be applied to the data collector 130. Information, zone level information, data transmission period information, and data accumulation amount data that can be transmitted can be set and applied.

For example, when the sensing period information is set to 30 seconds and the data transmission period information is set to 1 hour in the first sensor 110, the first sensor 110 detects an object every 30 seconds and correspondingly senses the same. Data may be generated, and the sensing data may be transmitted to the second sensor 120 or the data collector 130 at an interval of one hour.

In another example, when the data accumulation amount information is set to 1 MB and the data transmission period is set to 1 hour in the data collector 130, the data collector 130 may accumulate the sensing data by 1 MB or more or may have an hour period. In case of arrival, the sensing data may be transmitted to the server 140.

At this time, when there is a change request for the operation setting from the customer, the server 140 may change the operation setting to correspond to the change request. That is, when the server 140 requests a change of the operation setting from the customer, the server 140 may provide sensing period information, level information for each sensing data, level information for each zone, data transmission period information, or data accumulation amount information for data transmission. Changes can be made to meet customer change requests.

For example, if a customer requests a change to a cockroach (level 1), a mouse (level 2), a fly (level 3) or an ant (level 4) for pest related information, the server 140 may change the customer. In order to comply with the request, the level information may be used in the existing level information of rats (level 1), cockroaches (level 2), ants (level 3), flies (level 4), cockroaches (level 1), mice (level 2), Can be changed to Fly (Level 3) or Ant (Level 4).

In addition, the server 140 may reflect the operation setting to the selected condition, and analyze and process the sensing data based on the condition in which the operation setting is reflected. For example, the server 140 may set and apply the level information for each data to the data collector 130, and may reflect the data level information to the selected condition in association with the data collector 130. Accordingly, the server 140 may classify the sensing data for each level assigned to the sensing data and analyze and process the sensing data based on the condition in which the level information for each data is reflected.

The server 140 may monitor the processed sensing data and transmit a predetermined work command signal associated with the sensing data to the terminal of the worker based on the monitoring result. That is, the server 140 determines whether to transmit the work command signal using the monitoring result, and when it is determined that the work command signal is transmitted, the server 140 transmits the work command signal associated with the sensing data to a terminal of a worker (not shown). Can be sent to. Here, the work command signal may include a command signal for work related to control, security / safety, or hygiene / environment.

In this case, the server 140 may identify the location information of the first sensor 110 with reference to a database (not shown), and transmit the work command signal to one of the terminals of the worker in close proximity to the identified location information. . That is, the server 140 may search for the location of the terminal of the worker that is close to the location information of the first sensor 110 by using a location tracking system such as a global positioning system (GPS). The operation command signal may be transmitted to the. Here, the server 140 preferably transmits the work command signal to the terminal of the worker closest to the location information of the first sensor 110.

For example, if the location information of the first sensor 110 is 'Yeoksam-dong', the server 140 searches for the terminal of the worker located in 'Yeoksam-dong' using the location tracking system, and one of the searched terminal of the worker The operation command signal may be transmitted to the. If the terminal of the worker located in 'Yeoksam-dong' is not searched, the server 140 searches for the terminal of the worker located in 'Gangnam-gu' using the location tracking system, and the one of the searched terminal of the worker The work command signal can be transmitted.

At this time, the server 140 identifies the work schedule of the worker in proximity to the location information of the first sensor 110 with reference to the database, and the work command to one of the terminals of the worker based on the identified work schedule. You can send a signal. For example, if a worker located closest to the location information of the first sensor 110 is performing another job due to a different job schedule or is about to perform a job soon, the server 140 may determine that another worker has a blank job schedule. The work command signal may be transmitted to a terminal.

The server 140 may store the work performed by the worker according to the work command signal in the database. When the work command signal is a command signal related to the control of pests, the server 140 may store the contents of the control work, such as pest control, in the database. In addition, the server 140 may store the information on the place (the customer's home or the company) where the pests occurred, together with the control task execution contents, in the database.

When the sensing data satisfies the selected criterion, the server 140 may transmit predetermined alarm data to an alarm so that the alarm data may be output through the alarm. Here, the selected criterion may be whether the sensing data reaches the allowable transmission rate of the data collector 130.

Thus, the alarm data enables the customer to be aware of the presence or capture of pests or the intrusion of intruders. In addition, the customer can be aware of the occurrence of a safety accident such as a gas leak, fire, etc. through the alarm data. Here, the alarm data may include voice data, text data, image data, or image data.

In addition, the server 140 may transmit the alarm data to the terminal of the customer. Thus, even when the customer is far from home or company, the customer can receive the alarm data through the terminal of the customer, which causes the occurrence of pests or traps, intruders, safety incidents, etc. It is easy to see from a remote location.

In addition, the data communication control system according to the embodiment of the present invention may further include a coordinator although not shown in the drawings.

The coordinator may bidirectionally communicate with the first sensor 110 using the first communication scheme, and may receive the sensing data through the first communication scheme. The coordinator may bidirectionally communicate with the second sensor 120 using the third communication method, and receive the sensing data from the second sensor 120 through the third communication method. Here, the first communication method may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485, and the third communication method may include a ZigBee protocol.

The coordinator may bidirectionally communicate with the data collector 130 using a fourth communication method, and transmit the sensing data to the data collector 130 through the fourth communication method. In this case, the fourth communication scheme may include Ethernet or a serial protocol.

The coordinator may include a network extension module. The network expansion module serves to further expand the network connection. For example, for large businesses, the network expansion module allows for further expansion of network connections between buildings (or floors in buildings).

Such a coordinator may be controlled by the server 140 in its operation setting. That is, the coordinator may control operation settings such as data transmission period information or data accumulation amount information capable of data transmission by the server 140. The coordinator may transmit the sensing data to the data collector 130 based on the operation setting.

Hereinafter, the data communication control system according to an embodiment of the present invention will be described in detail by dividing each network by size.

2 is a diagram illustrating an example in which a data communication control system according to an embodiment of the present invention is applied to a small business or home.

2, a data communication control system according to an embodiment of the present invention may include a first sensor 110, a data collector 130, and a server 140.

The first sensor 110 may be installed in a small business place or home. The first sensor 110 may include a pest control sensor, a security sensor, an environmental hygiene sensor, and the like. The pest control sensor may include a wheel trap, a rat feeder, or a reptile. The first sensor 110 may generate pest-related information as sensing data through the pest control sensor.

The security sensor may include a smoke / gas sensor, a fire sensor, an infrared sensor, a camera, a motion detection sensor, a door open / close sensor, an impact sensor, or a pyroelectric sensor. The first sensor 110 may generate security / safety related information as the sensing data through the security sensor.

The environmental hygiene sensor may include a carbon dioxide sensor, a VOC sensor, a temperature sensor, a humidity sensor, a dust sensor, a gas sensor, a power sensor, or a water sensor. The first sensor 110 may generate environment / hygiene related information as the sensing data through the environmental hygiene sensor.

The first sensor 110 may bidirectionally communicate with the data collector 130 using a first communication method, and transmit the sensing data to the data collector 130 through the first communication method. Here, the first communication scheme may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485.

The data collector 130 may bidirectionally communicate with the first sensor 110 using the first communication method, and receive and store the sensing data from the first sensor 110 through the first communication method. . The data collector 130 bidirectionally communicates with the second sensor 120 using the third communication method, and the server 140 receives the sensing data received and stored from the second sensor 120 through the third communication method. ) Can be sent. Here, the third communication method may include a ZigBee protocol.

The data collector 130 may process the sensing data according to an operation set by the server 140. That is, the data collector 130 may transmit the sensing data to the server 140 according to the data transmission period information set by the server 140. Alternatively, the data collector 130 may transmit the sensing data to the server 140 according to data accumulation amount information capable of data transmission set by the server 140.

The server 140 bidirectionally communicates with the data collector 130 using a second communication method, and receives the sensing data from the data collector 130 through the second communication method based on a predetermined condition. Can be processed. Here, the selected condition may include level information for each sensing data or level information for each zone. In addition, the second communication scheme may include Code Division Multiple Access (CDMA), Ethernet, Internet, or Public Switched Telephone Network (PSTN).

When the selected condition is level information for each sensing data, the server 140 may classify and analyze and process the sensing data based on the level information for each sensing data. That is, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority.

In addition, when the selected condition is level information for each zone, the server 140 may classify and analyze and process the sensing data based on the level information for each zone. That is, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. In this case, it is assumed that the first sensor 110 is distributed and installed in each area (place). For example, the first sensor 110 may be distributed and installed in a production line, a raw material warehouse, an office, and the like.

The server 140 may control operation settings of the first sensor 110 and the data collector 130. Here, the operation setting may include sensing period information, level information for each sensing data, level information for each region, data transmission period information, or data accumulation amount information for data transmission. In other words, the server 140 may set and apply sensing period information, data transmission period information, and the like to the first sensor 110. In the data collector 130, level information for each sensing data, level information for each zone, It is possible to set and apply data transmission period information and data accumulation amount information that can be transmitted.

When there is a change request for the operation setting from a customer, the server 140 may change the operation setting to correspond to the change request. That is, when the server 140 requests a change of the operation setting from the customer, the server 140 may provide sensing period information, level information for each sensing data, level information for each zone, data transmission period information, or data accumulation amount information for data transmission. Changes can be made to meet customer change requests.

The server 140 may reflect the operation setting to the selected condition, and analyze and process the sensing data based on the condition in which the operation setting is reflected. For example, the server 140 may set and apply the level information for each data to the data collector 130, and may reflect the data level information to the selected condition in association with the data collector 130. Accordingly, the server 140 may classify the sensing data for each level assigned to the sensing data and analyze and process the sensing data based on the condition in which the level information for each data is reflected.

The server 140 may monitor the processed sensing data and transmit a predetermined work command signal associated with the sensing data to the terminal of the worker based on the monitoring result. That is, the server 140 determines whether to transmit the work command signal using the monitoring result, and when it is determined that the work command signal is transmitted, the server 140 transmits the work command signal associated with the sensing data to a terminal of a worker (not shown). Can be sent to. Here, the work command signal may include a command signal for work related to control, security / safety, or hygiene / environment.

In this case, the server 140 may identify the location information of the first sensor 110 with reference to a database (not shown), and transmit the work command signal to one of the terminals of the worker in close proximity to the identified location information. . That is, the server 140 may search for the location of the terminal of the worker that is close to the location information of the first sensor 110 by using a location tracking system such as a global positioning system (GPS). The operation command signal may be transmitted to the. Here, the server 140 preferably transmits the work command signal to the terminal of the worker closest to the location information of the first sensor 110.

In addition, the server 140 identifies the work schedule of the worker in proximity to the position information of the first sensor 110 with reference to the database, and the work command to one of the terminal of the worker based on the identified work schedule. You can send a signal. For example, if a worker located closest to the location information of the first sensor 110 is performing another job due to a different job schedule or is about to perform a job soon, the server 140 may determine that another worker has a blank job schedule. The work command signal may be transmitted to a terminal.

The server 140 may store the work performed by the worker according to the work command signal in the database. When the work command signal is a command signal related to the control of pests, the server 140 may store the contents of the control work, such as pest control, in the database. In addition, the server 140 may store the information on the place where the pest is generated (the small business or the home) together with the contents of the control work in the database.

When the sensing data satisfies the selected criterion, the server 140 may transmit predetermined alarm data to an alarm so that the alarm data may be output through the alarm. Here, the selected criterion may be whether the sensing data reaches the allowable transmission rate of the data collector 130.

Thus, the alarm data enables the customer to be aware of the presence or capture of pests or the intrusion of intruders. In addition, the customer can be aware of the occurrence of a safety accident such as a gas leak, fire, etc. through the alarm data. Here, the alarm data may include voice data, text data, image data, or image data.

In addition, the server 140 may transmit the alarm data to the terminal of the customer. Thus, even when the customer is far from home or company, the customer can receive the alarm data through the terminal of the customer, which causes the occurrence of pests or traps, intruders, safety incidents, etc. It is easy to see from a remote location.

3 is a diagram illustrating an example in which a data communication control system according to an exemplary embodiment of the present invention is applied to a medium-sized business place.

Referring to FIG. 3, a data communication control system according to an embodiment of the present invention may include a first sensor 110, a second sensor 120, a data collector 130, and a server 140.

The first sensor 110 may be installed at a medium-sized business place. The first sensor 110 may include a pest control sensor, a security sensor, an environmental hygiene sensor, and the like. The pest control sensor may include a wheel trap, a rat feeder, or a reptile. The first sensor 110 may generate pest-related information as sensing data through the pest control sensor.

The security sensor may include a smoke / gas sensor, a fire sensor, an infrared sensor, a camera, a motion detection sensor, a door open / close sensor, an impact sensor, or a pyroelectric sensor. The first sensor 110 may generate security / safety related information as the sensing data through the security sensor.

The environmental hygiene sensor may include a carbon dioxide sensor, a VOC sensor, a temperature sensor, a humidity sensor, a dust sensor, a gas sensor, a power sensor, or a water sensor. The first sensor 110 may generate environment / hygiene related information as the sensing data through the environmental hygiene sensor.

The first sensor 110 may bidirectionally communicate with the second sensor 120 using a first communication method, and transmit the sensing data to the second sensor 120 through the first communication method. In addition, the first sensor 110 may communicate with the data collector 130 bidirectionally using a first communication scheme, and may transmit the sensing data to the data collector 130 through the first communication scheme. Here, the first communication scheme may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485.

The second sensor 120 may bidirectionally communicate with the first sensor 110 using the first communication method, and receive the sensing data from the first sensor 110 through the first communication method. In addition, the second sensor 120 bidirectionally communicates with the data collector 130 using a third communication method, and transmits the sensing data to the data collector 130 through the third communication method. Here, the third communication method may include a ZigBee protocol.

The second sensor 120 may include a sensor expansion module that can expand by adding the connection number of the first sensor 110. The second sensor 120 may be configured to connect up to 200 first sensors 110 to one second sensor 120 using the sensor expansion module.

The second sensor 120 may further include a router module capable of performing a routing and addressing function. The second sensor 120 may perform routing and addressing with respect to the first sensor 110 using the router module. For example, when the second sensor 120 sends data (packet) to the first sensor 110, the second sensor 120 searches for an address of the first sensor 110 that is a destination to receive the data by using the router module. The data may be sent to the address of the discovered first sensor 110 in the shortest (or optimal) path. The second sensor 120 may be installed in the medium-sized business place. Meanwhile, the router module may be mounted on the data collector 130.

Like the first sensor 110, the second sensor 120 may generate the sensing data. In this case, the second sensor 120, like the first sensor 110, may include a pest control sensor, a security sensor, an environmental hygiene sensor, and the like.

The data collector 130 may bidirectionally communicate with the first sensor 110 using the first communication method, and receive and store the sensing data from the first sensor 110 through the first communication method. The data collector 130 bidirectionally communicates with the second sensor 120 using the third communication method, and stores the sensing data received and stored from the second sensor 120 through the third communication method. 140).

The data collector 130 may process the sensing data according to an operation set by the server 140. That is, the data collector 130 may transmit the sensing data to the server 140 according to the data transmission period information set by the server 140. Alternatively, the data collector 130 may transmit the sensing data to the server 140 according to data accumulation amount information capable of data transmission set by the server 140.

For example, when the data transmission period information is 30 minutes by the server 140, the data collector 130 may transmit the sensing data to the server 140 every 30 minutes. For another example, when the data accumulation amount information that can be transmitted by the server 140 is 500 KB, the data collector 130 may transmit the sensing data to the server 140 when the data accumulation amount information reaches or exceeds 500 KB. ) Can be sent.

The server 140 bidirectionally communicates with the data collector 130 using a second communication method, receives the sensing data from the data collector 130 through the second communication method, and selects the received sensing data. Analyze and process based on the conditions specified. Here, the selected condition may include level information for each sensing data or level information for each zone. In addition, the second communication scheme may include Code Division Multiple Access (CDMA), Ethernet, Internet, or Public Switched Telephone Network (PSTN).

When the selected condition is level information for each sensing data, the server 140 may classify and analyze and process the sensing data based on the level information for each sensing data. That is, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority.

For example, when the sensing data is the pest related information, the level information for each sensing data may be classified by pest species such as rat (level 1), cockroach (level 2), ant (level 3), and fly (level 4). It may be given level information. In this case, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority. That is, the server 140 determines the priority in order of rat-> cockroach-> ant-> fly using the level information for each sensing data, and according to the determined priority, the sensing data (rat, cockroach, ant, Appearance information, capture information, capture number information, etc. of each fly can be analyzed and processed.

When the selected condition is level information for each zone, the server 140 may classify and analyze and process the sensing data based on the level information for each zone. That is, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. In this case, it is assumed that the first sensor 110 is distributed and installed in each area (place). For example, the first sensor 110 may be distributed and installed in a production line, a raw material warehouse, an office, and the like.

For example, when the sensing data is the security related information, the level information for each zone may be a raw material warehouse (level 1), a production line (level 2), or an office (level 3). In this case, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. That is, the server 140 determines priority of the raw material warehouse-> production line-> office using the level information for each zone, and analyzes and processes the sensing data (intruder information) according to the determined priority. Can be.

The server 140 may control operation settings of the first sensor 110, the second sensor 120, and the data collector 130. Here, the operation setting may include sensing period information, level information for each sensing data, level information for each region, data transmission period information, or data accumulation amount information for data transmission.

That is, the server 140 may set and apply sensing period information, data transmission period information, and the like to the first sensor 110 or the second sensor 120, and provide level information for each sensing data to the data collector 130. Zone level information, data transmission period information, and data accumulation amount data that can be transmitted can be set and applied.

For example, when the sensing period information is set to 30 seconds and the data transmission period information is set to 1 hour in the first sensor 110, the first sensor 110 detects an object every 30 seconds and correspondingly senses the same. Data may be generated, and the sensing data may be transmitted to the second sensor 120 or the data collector 130 at an interval of one hour.

In another example, when the data accumulation amount information is set to 1 MB and the data transmission period is set to 1 hour in the data collector 130, the data collector 130 may accumulate the sensing data by 1 MB or more or may have an hour period. In case of arrival, the sensing data may be transmitted to the server 140.

At this time, when there is a change request for the operation setting from the customer, the server 140 may change the operation setting to correspond to the change request. That is, when the server 140 requests a change of the operation setting from the customer, the server 140 may provide sensing period information, level information for each sensing data, level information for each zone, data transmission period information, or data accumulation amount information for data transmission. Changes can be made to meet customer change requests.

For example, if a customer requests a change to a cockroach (level 1), a mouse (level 2), a fly (level 3) or an ant (level 4) for pest related information, the server 140 may change the customer. In order to comply with the request, the level information may be used in the existing level information of rats (level 1), cockroaches (level 2), ants (level 3), flies (level 4), cockroaches (level 1), mice (level 2), Can be changed to Fly (Level 3) or Ant (Level 4).

The server 140 may reflect the operation setting to the selected condition, and analyze and process the sensing data based on the condition in which the operation setting is reflected. For example, the server 140 may set and apply the level information for each data to the data collector 130, and may reflect the data level information to the selected condition in association with the data collector 130. Accordingly, the server 140 may classify the sensing data for each level assigned to the sensing data and analyze and process the sensing data based on the condition in which the level information for each data is reflected.

The server 140 may monitor the processed sensing data and transmit a predetermined work command signal associated with the sensing data to the terminal of the worker based on the monitoring result. That is, the server 140 determines whether to transmit the work command signal using the monitoring result, and when it is determined that the work command signal is transmitted, the server 140 transmits the work command signal associated with the sensing data to a terminal of a worker (not shown). Can be sent to. Here, the work command signal may include a command signal for work related to control, security / safety, or hygiene / environment.

The server 140 may identify the location information of the first sensor 110 with reference to a database (not shown), and transmit the work command signal to one of the terminals of the worker in proximity to the identified location information. That is, the server 140 may search for the location of the terminal of the worker that is close to the location information of the first sensor 110 by using a location tracking system such as a global positioning system (GPS). The operation command signal may be transmitted to the. Here, the server 140 preferably transmits the work command signal to the terminal of the worker closest to the location information of the first sensor 110.

The server 140 identifies the work schedule of the worker in proximity to the location information of the first sensor 110 with reference to the database, and transmits the work command signal to one of the terminals of the worker based on the determined work schedule. Can transmit For example, if a worker located closest to the location information of the first sensor 110 is performing another job due to a different job schedule or is about to perform a job soon, the server 140 may determine that another worker has a blank job schedule. The work command signal may be transmitted to a terminal.

The server 140 may store the work performed by the worker according to the work command signal in the database. When the work command signal is a command signal related to the control of pests, the server 140 may store the contents of the control work, such as pest control, in the database. In addition, the server 140 may store the information on the place where the pests occurred (the medium-sized business establishment) together with the contents of the control work in the database.

When the sensing data satisfies the selected criterion, the server 140 may transmit predetermined alarm data to an alarm so that the alarm data may be output through the alarm. Here, the selected criterion may be whether the sensing data reaches the allowable transmission rate of the data collector 130.

Thus, the alarm data enables the customer to be aware of the presence or capture of pests or the intrusion of intruders. In addition, the customer can be aware of the occurrence of a safety accident such as a gas leak, fire, etc. through the alarm data. Here, the alarm data may include voice data, text data, image data, or image data.

In addition, the server 140 may transmit the alarm data to the terminal of the customer. Thus, even when the customer is far from home or company, the customer can receive the alarm data through the terminal of the customer, which causes the occurrence of pests or traps, intruders, safety incidents, etc. It is easy to see from a remote location.

4 is a diagram illustrating an example in which a data communication control system according to an exemplary embodiment of the present invention is applied to a large-scale workplace.

Referring to FIG. 4, a data communication control system according to an embodiment of the present invention includes a first sensor 110, a second sensor 120, a data collector 130, a coordinator 150, and a server 140. can do.

The first sensor 110 may be installed in a large business place. The first sensor 110 may include a pest control sensor, a security sensor, an environmental hygiene sensor, and the like. The pest control sensor may include a wheel trap, a rat feeder, or a reptile. The first sensor 110 may generate pest-related information as sensing data through the pest control sensor.

The security sensor may include a smoke / gas sensor, a fire sensor, an infrared sensor, a camera, a motion detection sensor, a door open / close sensor, an impact sensor, or a pyroelectric sensor. The first sensor 110 may generate security / safety related information as the sensing data through the security sensor.

The environmental hygiene sensor may include a carbon dioxide sensor, a VOC sensor, a temperature sensor, a humidity sensor, a dust sensor, a gas sensor, a power sensor, or a water sensor. The first sensor 110 may generate environment / hygiene related information as the sensing data through the environmental hygiene sensor.

The first sensor 110 may bidirectionally communicate with the second sensor 120 using a first communication method, and transmit the sensing data to the second sensor 120 through the first communication method. In addition, the first sensor 110 may communicate with the data collector 130 bidirectionally using a first communication scheme, and may transmit the sensing data to the data collector 130 through the first communication scheme. Here, the first communication scheme may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485.

The second sensor 120 may bidirectionally communicate with the first sensor 110 using the first communication method, and receive the sensing data from the first sensor 110 through the first communication method. In addition, the second sensor 120 may bidirectionally communicate with the data collector 130 using a third communication method, and transmit the sensing data to the data collector 130 through the third communication method. In addition, the second sensor 120 may bidirectionally communicate with the coordinator 150 using the third communication method, and transmit the sensing data to the coordinator 150 through the third communication method. Here, the third communication method may include a ZigBee protocol.

The second sensor 120 may include a sensor expansion module that can expand by adding a connection number of the first sensor 110. The second sensor 120 may further include a router module capable of performing a routing and addressing function. The second sensor 120 may perform routing and addressing with respect to the first sensor 110 using the router module. Such a second sensor 120 may be installed in a large-scale workplace. The router module may be mounted on the data collector 130 and the coordinator 150.

Like the first sensor 110, the second sensor 120 may generate the sensing data. In this case, the second sensor 120 may include a pest control sensor, a security sensor, an environmental hygiene sensor, and the like as the first sensor 110.

The data collector 130 may bidirectionally communicate with the first sensor 110 using the first communication method, and receive and store the sensing data from the first sensor 110 through the first communication method. The data collector 130 bidirectionally communicates with the second sensor 120 using the third communication method, and the server 140 receives the sensing data received and stored from the second sensor 120 through the third communication method. To send). Here, the third communication method may include a ZigBee protocol.

The data collector 130 may process the sensing data according to an operation set by the server 140. That is, the data collector 130 may transmit the sensing data to the server 140 according to the data transmission period information set by the server 140. Alternatively, the data collector 130 may transmit the sensing data to the server 140 according to data accumulation amount information capable of data transmission set by the server 140.

The coordinator 150 may bidirectionally communicate with the first sensor 110 using the first communication scheme, and may receive the sensing data through the first communication scheme. In addition, the coordinator 150 may bidirectionally communicate with the second sensor 120 using the third communication method, and may receive the sensing data from the second sensor 120 through the third communication method.

The coordinator 150 may bidirectionally communicate with the data collector 130 using the fourth communication method, and transmit the sensing data to the data collector 130 through the fourth communication method. In this case, the fourth communication scheme may include Ethernet or a serial protocol.

Coordinator 150 may include a network expansion module that can further expand the network connection. The coordinator 150 may further expand the network connection between buildings or floors in the building using the network extension module, for example, in a large-scale workplace.

FIG. 5 is a diagram illustrating an example of a network configuration using a coordinator in a large-scale workplace in a data communication control system according to an exemplary embodiment of the present invention.

As shown in FIG. 5, the coordinator 150 may be installed on the first floor and the second and third floors in which the data collector 130 is installed. The coordinator 150 installed on the second floor is implemented to communicate using a wireless communication method such as the data collector 130 and ZigBee, and the coordinator 150 installed on the third floor is the data collector 130. It can communicate using a wired communication method such as and Ethernet. That is, the coordinator 150 installed on the floor close to the data collector 130 communicates with the data collector 130 wirelessly, and the coordinator 150 installed on the floor far from the data collector 130 may operate the data collector 130. It can communicate with wired.

The coordinator 150 may receive the sensing data from the first sensor 110 and the second sensor 120 and transmit the sensing data to the data collector 130. The data collector 130 may receive the sensing data from the first sensor 110, the second sensor 120, and the coordinator 150.

Although not shown in the drawing, when constructing a building-to-building network in a large-scale workplace, the coordinator 150 wirelessly communicates with the data collector 130 installed in a nearby building, and communicates by wire with the data collector 130 installed in a distant building. can do.

Referring back to FIG. 4, the server 140 bidirectionally communicates with the data collector 130 using the second communication method, and receives the sensing data from the data collector 130 through the second communication method. Analysis and processing can be based on selected conditions. Here, the selected condition may include level information for each sensing data or level information for each zone.

When the selected condition is level information for each sensing data, the server 140 may classify and analyze and process the sensing data based on the level information for each sensing data. That is, the server 140 may determine the priority based on the level information for each sensing data, and analyze and process the sensing data according to the determined priority.

When the selected condition is level information for each zone, the server 140 may classify and analyze and process the sensing data based on the level information for each zone. That is, the server 140 may determine the priority based on the level information for each zone, and analyze and process the sensing data according to the determined priority. In this case, it is assumed that the first sensor 110 is distributed and installed in each area (place). For example, the first sensor 110 may be distributed and installed in a production line, a raw material warehouse, an office, and the like.

The server 140 may control operation settings of the first sensor 110, the second sensor 120, and the data collector 130. Here, the operation setting may include sensing period information, level information for each sensing data, level information for each region, data transmission period information, or data accumulation amount information for data transmission. That is, the server 140 may set and apply sensing period information, data transmission period information, and the like to the first sensor 110 or the second sensor 120, and provide level information for each sensing data to the data collector 130. Zone level information, data transmission period information, and data accumulation amount data that can be transmitted can be set and applied.

When there is a change request for the operation setting from a customer, the server 140 may change the operation setting to correspond to the change request. That is, when the server 140 requests a change of the operation setting from the customer, the server 140 may provide sensing period information, level information for each sensing data, level information for each zone, data transmission period information, or data accumulation amount information for data transmission. Changes can be made to meet customer change requests.

The server 140 may reflect the operation setting to the selected condition, and analyze and process the sensing data based on the condition in which the operation setting is reflected. For example, the server 140 may set and apply the level information for each data to the data collector 130, and may reflect the data level information to the selected condition in association with the data collector 130. Accordingly, the server 140 may classify the sensing data for each level assigned to the sensing data and analyze and process the sensing data based on the condition in which the level information for each data is reflected.

The server 140 may monitor the processed sensing data and transmit a predetermined work command signal associated with the sensing data to the terminal of the worker based on the monitoring result. That is, the server 140 determines whether to transmit the work command signal using the monitoring result, and when it is determined that the work command signal is transmitted, the server 140 transmits the work command signal associated with the sensing data to a terminal of a worker (not shown). Can be sent to. Here, the work command signal may include a command signal for work related to control, security / safety, or hygiene / environment.

In this case, the server 140 may identify the location information of the first sensor 110 with reference to a database (not shown), and transmit the work command signal to one of the terminals of the worker in close proximity to the identified location information. . That is, the server 140 may search for the location of the terminal of the worker that is close to the location information of the first sensor 110 by using a location tracking system such as a global positioning system (GPS). The operation command signal may be transmitted to the. Here, the server 140 preferably transmits the work command signal to the terminal of the worker closest to the location information of the first sensor 110.

In addition, the server 140 identifies the work schedule of the worker in proximity to the position information of the first sensor 110 with reference to the database, and the work command to one of the terminal of the worker based on the identified work schedule. You can send a signal. For example, if a worker located closest to the location information of the first sensor 110 is performing another job due to a different job schedule or is about to perform soon, the server 140 may perform another worker whose job schedule is empty. The work command signal may be transmitted to a terminal of the.

The server 140 may store the work performed by the worker according to the work command signal in the database. When the work command signal is a command signal related to the control of pests, the server 140 may store the contents of the control work, such as pest control, in the database. In addition, the server 140 may store the information on the place (large business place) in which the pests occurred, together with the control task execution contents, in the database.

When the sensing data satisfies the selected criterion, the server 140 may transmit predetermined alarm data to an alarm so that the alarm data may be output through the alarm. Here, the selected criterion may be whether the sensing data reaches the allowable transmission rate of the data collector 130.

Thus, the alarm data enables the customer to be aware of the presence or capture of pests or the intrusion of intruders. In addition, the customer can be aware of the occurrence of a safety accident such as a gas leak, fire, etc. through the alarm data. Here, the alarm data may include voice data, text data, image data, or image data.

In addition, the server 140 may transmit the alarm data to the terminal of the customer. Thus, even when the customer is far from home or company, the customer can receive the alarm data through the terminal of the customer, which causes the occurrence of pests or traps, intruders, safety incidents, etc. It is easy to see from a remote location.

6 to 8 are flowcharts illustrating a data processing method using a data communication control system according to an embodiment of the present invention.

First, referring to FIG. 6, in operation S610, the data collector 130 may receive and store sensing data generated by the first sensor 110 or the second sensor 120 using a first communication scheme. have. Here, the first communication method may include an IEEE 802.15.4 MAC (OOB) protocol or an RS 485. In addition, the first sensor 110 may include a control sensor, a security sensor, an environmental hygiene sensor, and the second sensor 120 may receive from the first sensor 110 without directly generating the sensing data. .

Next, the server 140 may receive the stored sensing data using the second communication method. In operation S620, the server 140 may determine whether the received sensing data satisfies a selected condition. As a result of determination, when the received sensing data satisfies the selected condition, the server 140 may perform step S630. On the other hand, if the received sensing data does not satisfy the selected condition, the server 140 may perform step S610 again. Here, the second communication method may include CDMA, Ethernet, Internet, or PSTN.

In operation S630, the server 140 may analyze and process the received sensing data based on a predetermined condition. Here, the selected condition may include level information for each sensing data or level information for each zone. When the selected condition is level information for each sensing data, the server 140 may classify and analyze and process the sensing data based on the level information for each sensing data. In addition, when the selected condition is the level information for each zone, the server 140 may classify and analyze and process the sensing data based on the level information for each zone.

Referring to FIG. 7, the server 140 determines a priority based on the level information for each sensing data or the level information for each zone as illustrated in FIG. 7 (S710). The sensing data may be analyzed and processed according to the priority (S720).

On the other hand, the server 140 may control the operation settings of the communication control system. That is, the server 140 may control operation settings of the first sensor 110, the second sensor 120, the data collector 130, and the coordinator 150. Here, the operation setting may include at least one of sensing period information, level information for each sensing data, level information for each region, a data transmission period, or data accumulation amount information for data transmission.

Referring to FIG. 8, the server 140 may reflect the operation setting to the selected condition (S810), and analyze and process the sensing data based on the condition in which the operation setting is reflected (S820).

Meanwhile, the server 140 may receive a change request for the operation setting from the customer. In this case, the server 140 may change the operation setting according to the received change request.

In step S640, the server 140 monitors the sensing data processed in step S630, and in step S650, the server 140 determines a predetermined work command associated with the sensing data based on the monitoring result. The signal can be sent to the operator's terminal. In this case, the server 140 may identify the generation position information (position information of the first sensor 110 or the second sensor 120) of the sensing data with reference to a database. When the generation position information of the sensing data is determined, the server 140 may transmit the work command signal to one of the terminal of the worker in close proximity to the determined position information.

In this case, the server 140 may determine the work schedule of the worker in proximity to the location information with reference to the database. When the work schedule of the worker is determined, the server 140 may transmit the work command signal to one of the terminals of the worker based on the determined work schedule.

In operation S660, the server 140 may store the work performed by the worker according to the work command signal in the database.

According to an exemplary embodiment of the present disclosure, when the sensing data satisfies a predetermined criterion, the server 140 may transmit predetermined alarm data to an alarm so that the alarm data may be output through the alarm. . Here, the selected criterion may be whether the sensing data has reached a transmission allowable value. In addition, the alarm data may include voice data, text data, image data, or image data. The server 140 may transmit the alarm data to the terminal of the customer.

Meanwhile, the communication control system may expand by adding the connection number of the first sensor 110 by using a sensor expansion module mounted on the second sensor 120. In addition, the communication control system may perform routing and addressing to the first sensor 110 using a routing module mounted on the second sensor 120.

In addition, according to an embodiment of the present invention, the second sensor 120 receives and stores sensing data generated by the first sensor 110 through a first communication scheme, and stores the stored sensing data in a third communication scheme. It can be transmitted to the data collector 130 or the coordinator 150 using the. Here, the third communication method may include a ZigBee protocol.

In addition, the coordinator 150 may further expand the network connection by using a network expansion module mounted therein. The coordinator 150 may receive the sensing data using the first communication method and transmit the received sensing data to the data collector 130 using the fourth communication method. In this case, the fourth communication method may include an Ethernet, ZigBee protocol, or serial protocol.

A data processing method using a data communication control system according to an embodiment of the present invention includes a computer readable medium including program instructions for performing operations implemented by various computers. The computer readable medium may include program instructions, local data files, local data structures, or the like, alone or in combination. The media may be those specially designed and constructed for the purposes of the present invention, or they may be of the kind well-known and available to those having skill in the computer software arts. Examples of computer-readable recording media include magnetic media such as hard disks, floppy disks, and magnetic tape, optical recording media such as CD-ROMs, DVDs, magnetic-optical media such as floppy disks, and ROM, RAM, flash memory, and the like. Hardware devices specifically configured to store and execute the same program instructions are included. The medium may be a transmission medium such as an optical or metal wire, a waveguide, or the like for transmitting a signal specifying a program command, a local data structure, or the like. Examples of program instructions include not only machine code generated by a compiler, but also high-level language code that can be executed by a computer using an interpreter or the like.

While specific embodiments of the present invention have been described so far, various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the claims below, but also by the equivalents of the claims.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

1 is a conceptual diagram of a data communication control system according to an embodiment of the present invention.

2 is a diagram illustrating an example in which a data communication control system according to an embodiment of the present invention is applied to a small business or home.

3 is a diagram illustrating an example in which a data communication control system according to an exemplary embodiment of the present invention is applied to a medium-sized business place.

4 is a diagram illustrating an example in which a data communication control system according to an exemplary embodiment of the present invention is applied to a large-scale workplace.

FIG. 5 is a diagram illustrating an example of a network configuration using a coordinator in a large-scale workplace in a data communication control system according to an exemplary embodiment of the present invention.

6 to 8 are flowcharts illustrating a data processing method using a data communication control system according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: first sensor

120: second sensor

130: data collector

140: server

150: coordinator

Claims (52)

A first sensor generating sensing data; A data collector configured to bidirectionally communicate with the first sensor using a first communication method, and receive and store the sensing data from the first sensor through the first communication method; A central server which bidirectionally communicates with the data collector using a second communication scheme, and receives the sensing data from the data collector through the second communication scheme, and analyzes and processes the data based on a predetermined condition; And A coordinator including a network expansion module that further extends a network connection between the first sensor and the data collector. Including, The central server, And control an operation setting for at least one of the first sensor, the data collector, or the coordinator. The method of claim 1, The selected condition includes level information for each sensing data, The central server, And classifying, analyzing, and processing the sensing data based on the level information. The method of claim 1, When the first sensor is distributed and installed for each zone, the selected condition includes level information for each zone. The central server, And classifying, analyzing, and processing the sensing data based on the level information. The method according to claim 2 or 3, The central server, And determine the priority based on the level information, and analyze and process the sensing data according to the determined priority. The method of claim 1, The operation setting, At least one of sensing period information, level information for each sensing data, level information for each zone, a data transmission period, and data accumulation amount information for data transmission; The central server, And reflecting the operation setting to the selected condition, and analyzing and processing the sensing data based on the condition in which the operation setting is reflected. The method of claim 1, The central server, And when there is a change request for the operation setting from a customer, changing the operation setting to correspond to the change request. The method of claim 1, The central server, And monitor the processed sensing data and transmit a predetermined work command signal associated with the sensing data to a terminal of an operator based on the monitoring result. Claim 8 was abandoned when the registration fee was paid. The method of claim 7, wherein The central server, And a position information of the first sensor by referring to a database, and transmitting the work command signal to one of the terminals of the worker in close proximity to the identified position information. Claim 9 was abandoned upon payment of a set-up fee. The central server, And a work schedule of the worker in proximity to the location information with reference to the database, and transmitting the work command signal to one of the terminals of the worker based on the identified work schedule. Claim 10 was abandoned upon payment of a setup registration fee. The method of claim 7, wherein The central server, And storing the work performed by the worker according to the work command signal in a database. The method of claim 1, The central server, And transmitting the predetermined alarm data to the alarm when the sensing data satisfies the selected criterion, so that the alarm data can be output through the alarm. Claim 12 was abandoned upon payment of a registration fee. The method of claim 11, The alarm data includes at least one of voice data, text data, image data, or video data. The central server, And transmitting the alarm data to a terminal of a customer. Claim 13 was abandoned upon payment of a registration fee. The method of claim 11, The criteria selected above, And whether the sensing data has reached a transmission allowance of the data collector. The method of claim 1, The first communication method includes any one of IEEE 802.15.4 MAC (OOB) protocol, RS 485 or Zigbee, The second communication scheme comprises any one of CDMA, Ethernet, Internet or PSTN. The method of claim 1, Further comprising a second sensor including a sensor expansion module that can be expanded by adding the connection number of the first sensor, The central server, And control the operation setting of the second sensor. The method of claim 15, The second sensor further comprises a router module. Claim 17 has been abandoned due to the setting registration fee. The method according to claim 15 or 16, The second sensor, And bidirectionally communicating with the first sensor using the first communication method, receiving the sensing data from the first sensor through the first communication method, And bidirectionally communicating with the data collector using a third communication method, and transmitting the sensing data to the data collector through the third communication method. Claim 18 was abandoned upon payment of a set-up fee. The method of claim 17, And said third communication scheme comprises a ZigBee protocol. delete The method of claim 1, The coordinator, Bidirectionally communicating with the first sensor using the first communication scheme, receiving the sensing data through the first communication scheme, And bidirectionally communicating with the data collector using a fourth communication scheme, and transmitting the sensing data to the data collector through the fourth communication scheme. Claim 21 has been abandoned due to the setting registration fee. The method of claim 20, The coordinator, And bidirectionally communicating with a second sensor using a third communication method, and receiving the sensing data from the second sensor through the third communication method. Claim 22 is abandoned in setting registration fee. The coordinator, And transmitting the sensing data to the data collector based on the operation setting. Claim 23 was abandoned upon payment of a set-up fee. The method of claim 20, The fourth communication scheme includes at least one of an Ethernet ZigBee protocol or a serial protocol. The method of claim 1, The first sensor includes a pest control sensor, The sensing data, And a pest related information generated by said pest control sensor. Claim 25 was abandoned upon payment of a registration fee. The method of claim 24, The pest control sensor includes at least one of a wheel trap, mouse feed box, or insect lamp, The pest related information, Cockroach appearance or capture information generated by the wheel trap, or Rat appearance or capture information generated by the rat feeder, or And information on the appearance or capture of at least one of the adventitious pest, mite, or ant generated by the insect trap. The method of claim 1, The first sensor includes a security sensor, The sensing data, And data relating to security / security generated by the security sensor. Claim 27 was abandoned upon payment of a registration fee. The method of claim 26, The security sensor includes at least one of a smoke / gas sensor, a fire sensor, an infrared sensor, a camera, a motion detection sensor, a door open / close sensor, an impact sensor, or a pyroelectric sensor, The security / safety related information, Smoke / gas generation information generated by the smoke / gas sensor, or Fire occurrence information generated by the fire sensor, or And an intruder information generated by at least one of the infrared sensor, a camera, a motion detection sensor, a door open / close detection sensor, an impact detection sensor, or a pyroelectric sensor. The method of claim 1, The first sensor includes an environmental hygiene sensor, The sensing data, And environmental / hygiene related information generated by the environmental hygiene sensor. Claim 29 was abandoned upon payment of a set-up fee. The method of claim 28, The environmental hygiene sensor includes at least one of carbon dioxide detection sensor, VOC sensor, temperature sensor, humidity sensor, dust sensor, gas sensor, power sensor, gas sensor, water sensor, The environment / hygiene related information, Carbon dioxide detection amount information generated by the carbon dioxide detection sensor, or Organic volatile matter detection amount information generated by the VOC sensor, or Temperature information generated by the temperature sensor, or Humidity information generated by the humidity sensor, or Dust detection amount information generated by the dust sensor, or Gas leakage information generated by the gas sensor, or Gas leakage information generated by the gas sensor, or And water leakage information or water leakage information generated by the water sensor. Claim 30 was abandoned upon payment of a registration fee. Generating, at the first sensor, sensing data; In a data collector, communicating upward with the first sensor using a first communication method, and receiving and storing the sensing data from the first sensor through the first communication method; At a central server, bidirectionally communicating with the data collector using a second communication scheme, receiving the sensing data from the data collector through the second communications scheme, and analyzing and processing the data based on a predetermined condition; In the coordinator, further extending a network connection between the first sensor and the data collector via a network expansion module; And Controlling, at the central server, an operation setting for at least one of the first sensor, the data collector, or the coordinator Data processing method using a data communication control system comprising a. delete Claim 32 was abandoned upon payment of a registration fee. 31. The method of claim 30, The selected condition includes level information for each sensing data, Classifying, analyzing, and processing the sensing data based on the level information Data processing method using a data communication control system comprising a. Claim 33 was abandoned upon payment of a registration fee. 31. The method of claim 30, When the first sensor is distributed and installed for each zone, the selected condition includes level information for each zone. The step of analyzing and processing based on the selected conditions, Classifying, analyzing, and processing the sensing data based on the level information Data processing method using a data communication control system comprising a. Claim 34 was abandoned upon payment of a registration fee. 34. The method of claim 32 or 33, The step of classifying, analyzing and processing the sensing data based on level information, Determining a priority based on the level information; And Analyzing and processing the sensing data according to the determined priority Claim 35 was abandoned upon payment of a registration fee. 31. The method of claim 30, The operation setting, At least one of sensing period information, level information for each sensing data, level information for each zone, a data transmission period, and data accumulation amount information for data transmission; The step of analyzing and processing based on the selected conditions, Reflecting the operation setting to the predetermined condition; And Analyzing and processing the sensing data based on the condition in which the operation setting is reflected; Data processing method using a data communication control system comprising a. Claim 36 was abandoned upon payment of a registration fee. 31. The method of claim 30, The step of controlling the operation setting, Receiving a change request for the operation setting from a customer; And Changing the operation setting in response to the received change request Data processing method using a data communication control system comprising a. Claim 37 was abandoned upon payment of a registration fee. 31. The method of claim 30, Monitoring the processed sensing data at the central server; And At the central server, transmitting a work command signal associated with the sensing data to a terminal of an operator based on the monitoring result; Data processing method using a data communication control system, characterized in that it further comprises. Claim 38 was abandoned upon payment of a registration fee. The method of claim 37, The step of transmitting a work command signal, Identifying occurrence location information of the sensing data by referring to a database; And Transmitting the work command signal to one of the terminal of the worker proximate the identified position information; Data processing method using a data communication control system comprising a. Claim 39 was abandoned upon payment of a registration fee. 39. The method of claim 38, The step of transmitting a work command signal, Identifying a work schedule of the worker in proximity to the location information by referring to the database; And Transmitting the work command signal to one of the terminal of the worker based on the identified work schedule Data processing method using a data communication control system, characterized in that it further comprises. Claim 40 was abandoned upon payment of a registration fee. The method of claim 37, Storing, at the central server, work performed by the worker according to the work command signal in a database; Data processing method using a data communication control system, characterized in that it further comprises. Claim 41 was abandoned upon payment of a set-up fee. 31. The method of claim 30, When the sensing data meets the selected criteria, Sending, at the central server, alarm data to an alarm, such that the alarm data is output through the alarm; Data processing method using a data communication control system, characterized in that it further comprises. Claim 42 was abandoned upon payment of a registration fee. The method of claim 41, wherein The alarm data includes at least one of voice data, text data, image data, or video data. Transmitting, at the central server, the alarm data to a terminal of a customer Data processing method using a data communication control system, characterized in that it further comprises. Claim 43 was abandoned when the set registration fee was paid. The method of claim 41, wherein The criteria selected above, And whether the sensed data has reached a transmission allowable value. Claim 44 was abandoned upon payment of a set-up fee. 31. The method of claim 30, The first communication method includes any one of IEEE 802.15.4 MAC (OOB) protocol, RS 485 or Zigbee, The second communication method comprises any one of CDMA, Ethernet, Internet or PSTN. Claim 45 was abandoned upon payment of a registration fee. 31. The method of claim 30, In the second sensor, expanding by adding the connection number of the first sensor using a sensor expansion module Data processing method using a data communication control system, characterized in that it further comprises. Claim 46 was abandoned upon payment of a registration fee. The method of claim 45, At the second sensor, performing routing and addressing to the sensor using a routing module Data processing method using a data communication control system, characterized in that it further comprises. Claim 47 was abandoned upon payment of a registration fee. 47. The method of claim 45 or 46, Receiving and storing the generated sensing data in the second sensor and transmitting the stored sensing data by using a third communication scheme Data processing method using a data communication control system, characterized in that it further comprises. Claim 48 was abandoned when the setup fee was paid. 49. The method of claim 47, And the third communication method includes a ZigBee protocol. delete Claim 50 was abandoned upon payment of a set-up fee. 31. The method of claim 30, In the coordinator, receiving the sensing data from the first sensor using the first communication scheme and transmitting the received sensing data to the data collector using a fourth communication scheme Data processing method using a data communication control system, characterized in that it further comprises. Claim 51 was abandoned upon payment of a registration fee. 51. The method of claim 50, The fourth communication method includes at least one of Ethernet, ZigBee protocol, or serial protocol. Claim 52 was abandoned upon payment of a registration fee. A computer-readable recording medium having recorded thereon a program for performing the method of any one of claims 30, 32, 33, 35-46, 50, or 51.

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