KR101041517B1 - Web - based weather monitoring system by using field server - Google Patents

Abstract

PURPOSE: A web-based weather monitoring system is provided to ensure excellent profitability and extendability since a sensor network is based and to enable the observation in a wide region since a standard weather information sharing function is added. CONSTITUTION: A web-based weather monitoring system using a field server comprises: at least one field server(100) transmitting the solar-radiation amount, CO2, temperature, humidity, and data of observed images to an agent through a network; and an integrated agent(200). The integrated agent comprises a data collection unit, a processing unit for changing the collected data to a network common data form, a central control unit for storing the processed data in weather monitoring database, and a sharing processing unit distributing data.

Description

Web-based weather monitoring system using field server {WEB-BASED WEATHER MONITORING SYSTEM BY USING FIELD SERVER}

The present invention relates to a web-based weather monitoring system using a field server, and more particularly, a field server for observing a nearby weather situation in real time using a ubiquitous sensor and transmitting the weather situation information to an integrated agent. The present invention relates to a web-based weather monitoring system using a field server including an integrated agent for managing and sharing weather condition information received from the field server.

The present invention relates to a web-based weather monitoring system using a field server.

In today's society, there are rapid changes in the environment due to global warming and El Niño, where temperatures rise due to increased emissions of pollutants such as carbon dioxide and deforestation due to industrialization and industrialization. Extreme weather events, such as heavy rains or wildfires, occur frequently.

Such extreme weather not only reduces business facilities by increasing production facilities damage, production disruptions and logistics costs, but also causes local damage in a very short time.

While the current weather forecasting system that monitors the above extreme weather forecasts for a wide range of regions through meteorological satellites, detailed weather information cannot be delivered to local places such as mountain valleys and riverside amusement parks. It remains defenseless.

In addition, since the central control agencies mostly provide weather information of the current time, and the weather information is also provided for a comprehensive area, as described above, the central control agency is effective in preventing disasters in case of local weather anomalies that may occur at a specific place. It's not working.

In other words, weather-related information is a weather forecast that depends on weather satellites or weather sites, and its effects are insignificant, and it is difficult to transmit real-time information to extreme events in a disaster prevention area.

In addition, in order to provide real-time meteorological disaster-related information using a wired communication network, it is necessary to actively install a meteorological observation system in a specific area. There was a problem. In addition, the equipment of the meteorological observation system was expensive, so it was difficult to install in many places in terms of cost.

The present invention has been invented to solve the above problems, the present invention uses a ubiquitous sensor in real time to observe a nearby weather situation, and transmits the weather information to the integrated agent (Field Server), and the It is an object of the present invention to provide a web-based weather monitoring system using an economical and scalable field server by including an integrated agent that manages and shares weather condition information received from a field server.

In order to achieve the above object, a web-based weather monitoring system using a field server according to the present invention generates observable values of solar radiation, CO ₂ , temperature and humidity at a point where a field server is installed using a ubiquitous sensor, and uses a camera. One or more field servers that capture the weather conditions around the field server to generate observation images, and transmit the solar radiation, CO ₂ , temperature, humidity observation values and observation images to the integrated agent through a network. ; And an integrated agent which processes and processes the solar radiation, CO ₂ , temperature, humidity observation values and observation images provided from the one or more field servers in a predetermined form and stores them in a weather monitoring database.

The field server preferably includes a network card and becomes one node of an IP-USN (Internet Protocol-Ubiquitous Sensor Network).

In addition, the field server, the network card; A solar radiation sensor for measuring the incident direction and intensity of solar radiation to generate solar radiation observations; CO ₂ sensor measures the concentration of carbon dioxide (CO ₂₎ for generating CO ₂ observations; A temperature sensor measuring the temperature to produce a temperature observation value; A humidity sensor measuring humidity to generate humidity observations; A camera for photographing a cloud cover (cloud, cloud, altitude) or rain or snow or yellow dust to generate an observation image; And a central processing unit for transmitting the solar radiation, CO ₂ , temperature, humidity observation values and observation images to an integrated agent through a wireless network.

On the other hand, the integration agent, the data collection unit for collecting the data after the data verification, the solar radiation amount, CO ₂ , temperature, humidity observation values and observation images provided from the at least one field server; A processing processor configured to process the solar radiation collected by the data collector, CO ₂ , temperature, humidity observation values, and the observed image into a network common data form (NetCDF); A central control unit for processing the solar radiation processed by the processing unit, CO ₂ , temperature, humidity observation values and observation images to be stored in a weather monitoring database; And receiving solar radiation amount, CO ₂ , temperature, humidity observation value, or observation image request, after performing the authentication procedure, the solar radiation amount, CO ₂ , temperature, humidity observation value stored in the weather monitoring database in the user terminal that has been authenticated. Or a sharing processor configured to process the observed image to be shared.

At this time, the sharing processing unit, it is preferable to distribute using the Hypertext Transfer Protocol (HTTP) of OPeNDAP (Open-source Project for a Network Data Access Protocol).

According to the present invention, the present invention observes a real-time weather situation using a ubiquitous sensor in real time, a field server for transmitting the weather condition information to an integrated agent, and weather condition information transmitted from the field server. By including an integrated agent that manages and manages shared processes, it is advantageous to provide a web-based weather monitoring system using an economical and scalable field server.

In addition, the present invention has the advantage that can be provided to the user in real time standard weather information continuously using a network access protocol.

In addition, since the present invention is based on a sensor network, it is more economical and expandable than general weather observation equipment, and the standard weather information sharing function is added to require real-time weather information as well as observation in an area with large geographical constraints. It is also very easy to provide data to users. That is, the present invention has the advantage of being able to escape the constraints of time and space.

1 is a system diagram showing the overall configuration of a web-based weather monitoring system using a field server according to a preferred embodiment of the present invention.
2 is a block diagram showing an internal configuration of the field server of FIG.
3 is a block diagram illustrating an internal configuration of the integration agent of FIG.
4 is an explanatory diagram showing an observation image photographed by a camera of a field server;
5 is an explanatory diagram showing that weather information is shared through a web browser by the integrated agent of the present invention.

Hereinafter, a preferred embodiment of a web-based weather monitoring system using a field server according to the present invention as described above will be described in detail with reference to the accompanying drawings.

1 is a system diagram showing the overall configuration of a web-based weather monitoring system using a field server according to a preferred embodiment of the present invention.

As shown, the present invention includes a field server 100 with an IP-USN and an integration agent 200.

The field server 100 generates observable values of solar radiation, CO ₂ , temperature and humidity at the point where the field server 100 is installed by using a ubiquitous sensor, and photographs weather conditions around the field server by using a network camera. An observation image is generated, and the solar radiation amount, CO ₂ , temperature, humidity observation value, and observation image are transmitted to the integration agent 200 through a network. At this time, the field server 100 is preferably installed for each predetermined area.

In addition, the field server 100 is provided with a network card to become one node of an Internet Protocol-Ubiquitous Sensor Network (IP-USN). As shown in FIG. 1, the ubiquitous sensor has an advantage that flexibility can be ensured because the adjacent sensor is connected through a wireless network even if one sensor stops observation.

In addition, the observed value from each sensor with the IP has the advantage that can be confirmed at any time through the web browser. The detailed configuration of the field server 100 will be described in more detail with reference to FIG. 2 below.

The integrated agent 200 processes the solar radiation, CO ₂ , temperature, humidity observation values and observation images provided from the one or more field servers 100 in a predetermined form and stores them in the weather monitoring database 250. The solar radiation, CO ₂ , temperature, humidity observations and observed images are processed to be shared with authorized users. Detailed configuration of the integration agent 200 will be described in more detail with reference to FIG. 2 below.

As described above, the use of the two concepts of ubiquitous sensors, web-based weather observation data and observation image sharing are the main points of the present invention.

FIG. 2 is a block diagram showing the internal configuration of the field server of FIG.

As shown in FIG. 2, the field server 100 includes a solar radiation sensor 110, a CO ₂ sensor 120, a temperature sensor 130, a humidity sensor 140, a network card 150, and a camera 160. , A storage unit 170 and a central processing unit 180.

The solar radiation sensor 110 is a ubiquitous sensor and measures the incident direction and the intensity of solar radiation to generate solar radiation observations.

The CO ₂ sensor 120 is a ubiquitous sensor and measures the concentration of carbon dioxide (CO ₂ ) to generate a CO ₂ observation value.

The temperature sensor 130 is a ubiquitous sensor and measures temperature to generate a temperature observation value.

The humidity sensor 140 is a ubiquitous sensor and measures humidity to generate humidity observation values.

The network card 150 enables an internet based sensor network. That is, as the network card 150 is provided, the network card 150 becomes a node of an IP-USN (Internet Protocol-Ubiquitous Sensor Network).

The camera 160 is a network camera, and generates an observation image by capturing a cloud covered state (eg, cloud cloudiness, cloud shape, altitude) or rain, snow, or yellow dust. 4 illustrates an observation image captured by the camera 160. As shown in FIG. 4, the observed image accurately indicates the degree of cloud cover and the presence or absence of rain and yellow dust.

The storage unit 170 includes the solar radiation sensor 110, the CO ₂ sensor 120, the temperature sensor 130, the humidity sensor 140, and the solar radiation generated by the camera 160, CO ₂ , temperature, and humidity. Observation values and observation images are stored.

The central processing unit 180 transmits the solar radiation, CO ₂ , temperature, humidity observation values and observation images to the integration agent 200 through a wireless network.

3 is a block diagram showing the internal configuration of the integration agent of FIG.

As shown in FIG. 3, the integration agent 200 includes a data collector 210, a processing processor 220, a sharing processor 230, a central controller 240, and a weather monitoring database 250.

The data collection unit 210 collects the solar radiation, CO ₂ , temperature, humidity observation values, and observation images provided from one or more field servers 100 after data verification.

The processing unit 220 converts the solar radiation amount, CO ₂ , temperature, humidity observation value, and observation image collected by the data collection unit 210 into a NetCDF (Network Common Data Form).

When the sharing processor 230 receives a solar radiation amount, CO ₂ , temperature, humidity observation value, or observation image request, the sharing processor 230 performs an authentication procedure, and then obtains the authentication to a user who has obtained the solar radiation amount, CO ₂ , temperature stored in the weather monitoring database. In addition, the processing of humidity observations or observations can be shared. At this time, the sharing processing unit 230 is preferably distributed using the Hypertext Transfer Protocol (HTTP) of the PeNDAP (Open-source Project for a Network Data Access Protocol).

5 is an explanatory diagram showing that the weather information is shared by the sharing processor 230 through the web browser. As shown, the present invention has the advantage that it is possible to manage and share solar radiation, CO ₂ , temperature, humidity observation values or observation images through a web browser.

The central control unit 240 processes the solar radiation processed by the processing unit, CO ₂ , temperature, humidity observation values and observation images to be stored in the weather monitoring database 250.

The weather monitoring database 250 stores the solar radiation amount, CO ₂ , temperature, humidity observation value, and observation image processed by the processing processor 230. At this time, it is preferable to be stored in a table for each field server.

In the above, the present invention has been shown and described with respect to certain preferred embodiments. However, the present invention is not limited only to the above-described embodiment, and those skilled in the art to which the present invention pertains can make various changes without departing from the technical spirit of the present invention. Therefore, the scope of the present invention should not be limited to the specific embodiments, but should be construed as defined by the appended claims.

100: field server 110: solar radiation sensor
120: CO ₂ sensor 130: temperature sensor
140: humidity sensor 150: network card
160: camera 170: storage unit
180: central processing unit 200: integration agent
210: data collection unit 220: processing unit
230: shared processing unit 240: central control unit
250: weather monitoring database 300: user terminal

Claims (5)

Using the ubiquitous sensor, the solar radiation, CO ₂ , temperature and humidity observation values are generated at the point where the field server is installed, and the camera generates a observation image by photographing weather conditions around the field server, and the solar radiation amount, One or more field servers for transmitting CO ₂ , temperature, humidity observation values and observation images to the integrated agent via a network; And
A data collector configured to collect, after data verification, solar radiation, CO ₂ , temperature, humidity observation values and observation images provided from the at least one field server;
A processing unit for changing the solar radiation amount, CO ₂ , temperature, humidity observation value and observation image collected by the data collection unit into a NetCDF (Network Common Data Form),
A central control unit for processing the solar radiation processed by the processing unit, CO ₂ , temperature, humidity observation values and observation images to be stored in a weather monitoring database;
When the solar radiation, CO ₂ , temperature, humidity observation value or observation image request is inputted, the solar radiation amount, CO ₂ , temperature, humidity observation value stored in the weather monitoring database is stored in the user terminal that has been authenticated after performing the authentication procedure. An integrated agent including a sharing processing unit for distributing using an HTTP (Hypertext Transfer Protocol) of the Open-source Project for a Network Data Access Protocol (OPeNDAP) so that observation images can be shared; Web based weather monitoring system using.
The method of claim 1, wherein the field server,
Web-based weather monitoring system using a field server, characterized in that the network card is provided as one node of the IP-USN (Internet Protocol-Ubiquitous Sensor Network).
The method according to claim 1 or 2, wherein the field server,
Network card;
A solar radiation sensor for measuring the incident direction and intensity of solar radiation to generate solar radiation observations;
CO ₂ sensor measures the concentration of carbon dioxide (CO ₂₎ for generating CO ₂ observations;
A temperature sensor measuring the temperature to produce a temperature observation value;
A humidity sensor measuring humidity to generate humidity observations;
A camera for photographing a cloud covered state or rain or snow or yellow dust to generate an observation image; And
And a central processing unit for transmitting the solar radiation, CO ₂ , temperature, humidity observation values, and observation images to an integrated agent through a wireless network. 10. The method of claim 3,
The solar radiation sensor, the CO ₂ sensor, the temperature sensor, the humidity sensor is a ubiquitous sensor, web-based weather monitoring system using a field server. delete

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