KR20200128226A - Fine dust concentration prediction system - Google Patents

Abstract

The present invention relates to a fine dust concentration prediction system. According to the present invention, fine dust sensors are provided in a plurality of divided areas within a predetermined area such as a theme park or a nursing facility, and a main server receives the concentration of fine dust measured from the fine dust sensors, stores the same in the database, performs big data pattern analysis using the fine dust concentrations stored in the database, predicts the fine dust concentration for each divided area, and transmits not only the current fine dust concentration by region but also the future fine dust concentration to the smartphone of a user upon a user request. The fine dust concentration prediction system of the present invention includes: a user terminal for transmitting fine dust concentration prediction request information including an identification code of a predetermined divided area and predetermined date information to the main server in order to know the concentration of fine dust in a predetermined divided area of a predetermined date; a main server that inputs the identification code of the predetermined divided area and the predetermined date, as input data, into the artificial neural network for predicting the concentration of fine dust, and transmits fine dust concentration information of a corresponding segmented area of a predetermined period output from the fine dust concentration prediction artificial neural network to a user terminal; and a fine dust concentration detection unit having a fine dust measuring device equipped with a fine dust sensor is in each of the multiple divided areas to transmit fine dust concentration information detected by each fine dust sensor to the main server, wherein the main server forms big data by accumulating the received fine dust concentration information and meteorological information provided from the Meteorological Agency, and extracts the pattern of the fine dust concentration by applying the big data to the artificial neural network for detecting the pattern of fine dust concentration.

Description

Fine dust concentration prediction system

The present invention includes a fine dust sensor in each of a plurality of divided areas within a predetermined area such as a theme park or a nursing facility, the main server receives the fine dust concentration measured from the fine dust sensors and stores it in a database, and the main server is a database Fine dust concentration that predicts the fine dust concentration for each segment by performing big data pattern analysis using the fine dust concentrations stored in, and transmits not only the current fine dust concentration by region but also the future fine dust concentration to the user's smartphone. It relates to a prediction system.

Dust refers to particulate matter that floats or scatters in the air. Dust is classified into total dust (TSP, Total Suspended Particles), which is less than 50μm, and fine dust (PM, Particulate Matter), which has a very small particle size, depending on the size of the particles. Fine dust is further divided into fine dust (PM ₁₀ ) whose diameter is smaller than 10 μm and fine dust (PM _2.5 ) whose diameter is smaller than 2.5 μm, and PM _2.5 is mainly used as an international comparison standard. If PM ₁₀ is about 1/5~1/7 smaller than the diameter of human hair (50~70μm), PM _2.5 is very small, about 1/20~1/30 of the hair. The fine dust components are mainly air pollutants including sulfurous acid gas, nitrogen oxides, and lead.

Because fine dust is so small that it is invisible, it stays in the air. It may have a negative impact on health by infiltrating the lungs through the respiratory tract or moving into the body through blood vessels. The World Health Organization (WHO) has proposed air quality guidelines for fine dust (PM ₁₀ and PM _2.5 ) since 1987, and in 2013, the International Agency for Research on Cancer (IARC) under the World Health Organization Fine dust was designated as a group 1 carcinogen (Group 1) that has been confirmed to be carcinogenic to humans. The domestic environmental standard for fine dust is currently'less than 25㎛ per m3', which is more than twice as high as the WHO recommended standard.

In particular, a variety of patients are gathered in nursing homes and the like, and these patients have relatively weak resistance, so it is necessary to check the concentration of fine dust from time to time and to predict the future and prepare in advance.

Accordingly, the present invention includes a fine dust sensor in each of a plurality of divided areas within a predetermined area such as a theme park or a nursing facility, the main server receives the fine dust concentration measured from the fine dust sensors and stores it in the database, and the main server Fine dust, which predicts the fine dust concentration for each segment by performing big data pattern analysis using the fine dust concentrations stored in the database, and transmits not only the current fine dust concentration by region but also the future fine dust concentration to the user's smartphone. We propose a concentration prediction system.

Fine dust measurement methods are largely divided into manual and automatic measurement methods depending on the method of collecting fine dust, and the automatic measurement methods are largely beta gauge, light scattering method, TEOM (tapered element oscillating microbalance). Here, both the beta ray measurement method and the light scattering method are optical methods using light. Beta ray measurement method, also called beta attenuation monitor, is a method of measuring the concentration before and after collection by applying a beta ray to a collection tape that is wound over time like a tape.It is easy and convenient because it can be automatically measured, but it is difficult to measure in real time. It is measured in the minimum time unit and is generally measured in the unit of at least 1 hour, so it is inappropriate for use for monitoring the environment that changes frequently in a short time, so an auxiliary device such as a cascade impactor is required. In the light scattering method, when light is irradiated on particulate matter floating in the atmosphere, light is scattered by particulate matter. At this time, when light is irradiated on particulate matter with the same physical property, the amount of scattered light is proportional to the mass concentration. It is a method of measuring the amount of scattered light using this principle and obtaining the concentration of particulate matter from the value. The light scattering method has the advantage that real-time measurement is possible and portable, and it is possible to measure each particle size such as PM _2.5 , PM ₁₀ , TSP with one device at the same time, but it measures the number concentration of particles, and this is used as mass concentration. There may be some errors in the conversion process, but in general, this method is applied to many types of fine dust measuring devices.

In general, the measured data is transmitted to a cloud server using short-range wireless communication.However, there are WIFI, Bluetooth, and IoT modules as short-range wireless networks, but all have distance limitations, so a dense network is required to transmit data within a certain area. There is a downside to configuring.

Therefore, the present invention uses a sensor to which a light scattering method capable of real-time measurement is applied, and a short-range communication method capable of collecting data regardless of a relatively distance, the Internet of Things (IoT) dedicated network LoRa built by SK Telecom. The network is used to transmit the measured fine dust concentration to the main server, and the main server analyzes the stored big data to extract patterns by time, season, and weather of fine dust, and predicts and alarms based on this. A system for predicting the concentration of fine dust is proposed.

As a prior art, the fine dust measuring system and method of Korean Patent Registration No. 10-1915704 includes a plurality of measuring devices, a user terminal and a measuring server, and the fine dust information is recalled according to the request of the fine dust information of the user terminal. It includes a measurement server for transmission to the user terminal. In the case of Korean Patent No. 10-1915704, the concentration of fine dust cannot be predicted in advance.

As another prior art, the system and method for determining the fine dust concentration of Korean Laid-Open Patent Publication No. 10-2015-0049433 uses auto-correlation and cross-correlation of block data composed of time index data and beta-line intensity average values to calculate parameters of approximate functions. And a beta-line strength predictor for predicting beta-line strength by calculating an estimate of the beta-line strength data of the data segment block data noise-removed from the approximation function estimated by the parameter calculating unit; and the beta-line strength predicting unit. It includes a concentration calculator for calculating the concentration of fine dust using the estimated value of the beta ray intensity data. Even in Korean Patent Publication No. 10-2015-0049433, the concentration of fine dust cannot be predicted in advance.

As another prior art, the method for measuring the concentration of fine dust using the smart phone application of Korean Patent Publication No. 10-2015-0070692 and the fine dust sensor device combined with the smart phone, uses a signal detected from the fine dust sensor device to the smart phone terminal. It is transmitted to the service operating system through the service operating system, and the service operating system processes the data and transmits it to the smartphone terminal for output. Even in Korean Patent Application Publication No. 10-2015-0070692, the concentration of fine dust cannot be predicted in advance.

The technical problem to be achieved by the present invention is to provide a fine dust sensor in each of a plurality of divided areas within a predetermined area such as a theme park or a nursing facility, and the main server receives the fine dust concentration measured from the fine dust sensors and stores it in a database. And, the main server performs big data pattern analysis using the fine dust concentrations stored in the database to predict the fine dust concentration for each segment, and not only the current fine dust concentration by region, but also the future fine dust concentration to the user's smartphone. It is to provide a system for predicting the concentration of fine dust that is transmitted.

Another technical problem to be achieved by the present invention is the Internet of Things (IoT) built by SK Telecom, a short-range communication method that uses a sensor to which a light scattering method capable of real-time measurement is applied and data can be collected without being restricted by a relatively distance. ) Dedicated network LoRa network is used to transmit the measured fine dust concentration to the main server, and the main server analyzes the stored big data to extract patterns by time, season, and weather of fine dust, and based on this It is to provide a system for predicting the concentration of fine dust, configured to perform prediction and warning.

In order to solve the above problem, the present invention transmits the fine dust concentration prediction request information including the identification code of the predetermined divided area and the predetermined date information to the main server in order to know the fine dust concentration of a predetermined divided area of a predetermined date. , User terminal; Prediction of fine dust concentration, inputting the identification code and predetermined date information of the divided area as input data into the artificial neural network, and transmitting the fine dust concentration information of the divided area of the predetermined date output from the fine dust concentration prediction artificial neural network to the user terminal. It characterized in that it comprises a;, the main server.

A fine dust measuring device equipped with a fine dust sensor is installed in each of the plurality of divided areas, and further includes a fine dust concentration detection unit that transmits fine dust concentration information detected by each fine dust sensor to the main server, and the main server receives Big data is formed by accumulating information on the concentration of fine dust and meteorological information provided by the Meteorological Agency, and extracting the pattern of the fine dust concentration by applying the big data to the artificial neural network for detecting the fine dust concentration pattern.

The main server extracts the fine dust concentration information of the divided area of the corresponding date by using the pattern of the fine dust concentration and big data from the fine dust concentration prediction artificial neural network.

Weather information is AWS (Automatic Weather System) measurement information and UM (Unified Model) weather information provided by the Meteorological Agency.

The main server comprises: a big data collection and classification system, which collects fine dust concentration and meteorological information, and classifies by date of each divided area to form big data; A fine dust concentration pattern extraction artificial neural network system for extracting a pattern of fine dust concentration by applying big data to a fine dust concentration pattern detection artificial neural network; It includes; a fine dust concentration prediction system for extracting fine dust concentration information of a corresponding divided area at a corresponding date by using the pattern and big data of the fine dust concentration in the artificial neural network.

The big data collection and classification system includes: a big data collection module for collecting fine dust concentration information received from the fine dust concentration detection unit and meteorological information provided by the Meteorological Agency; A big data classification and processing module that classifies and processes big data collected by the big data collection module; It includes; a big data storage unit that stores the big data worked in the big data classification and processing module.

The fine dust concentration pattern extraction artificial neural network system includes: an artificial neural network input layer classification module for performing a classification operation for applying the big data received from the big data storage unit to the fine dust concentration pattern extraction artificial neural network; A learning module based on an artificial neural network for extracting a fine dust concentration pattern using an artificial neural network for extracting a fine dust concentration pattern; And a fine dust concentration pattern database for storing data on the fine dust concentration pattern extracted from the artificial neural network-based learning module.

The fine dust concentration prediction system uses the fine dust concentration prediction artificial neural network, based on the data stored in the big data storage unit and the fine dust concentration pattern database, the fine dust concentration of the divided area of the corresponding date of the fine dust concentration prediction request information. A fine dust concentration prediction module that predicts; The fine dust concentration forecast that transmits the fine dust concentration received from the fine dust concentration prediction module to the user terminal, determines whether the fine dust concentration exceeds a preset reference value, and transmits a message notifying the danger status to the user terminal if it exceeds Module; includes.

The fine dust concentration pattern extraction artificial neural network is an artificial neural network that has been learned in advance to extract the pattern of the fine dust concentration using the fine dust concentration information received from the fine dust concentration detection unit and the meteorological information provided by the Meteorological Agency, and predicts the fine dust concentration. The artificial neural network is an artificial neural network that has been learned in advance to output the fine dust concentration of each divided area according to a date using data stored in the fine dust concentration pattern database and the data stored in the big data storage unit.

The fine dust concentration prediction system of the present invention includes a fine dust sensor in each of a plurality of divided areas within a predetermined area such as a theme park or a nursing facility, and the main server receives the fine dust concentration measured from the fine dust sensors to the database. And the main server performs big data pattern analysis using the fine dust concentrations stored in the database to predict the fine dust concentration for each segment, and not only the current fine dust concentration by region, but also the predicted future fine dust concentration. By sending to a smartphone, people who are vulnerable to fine dust, for example, patients, can check the concentration of fine dust from time to time, predict the future fine dust, and prepare in advance for fine dust in life activities such as appointments. have.

In addition, the present invention uses a sensor to which a light scattering method capable of real-time measurement is applied, and is made to transmit the measured fine dust concentration to the main server using a LoRa network, and the main server analyzes the stored big data to It is configured to extract patterns by time, season, and weather of dust, and make predictions and alarms based on them. Data can be collected regardless of distance than other short-range communication methods, and through analysis of big data, more accurate current The dust concentration of and future dust concentration can be output.

1 is an explanatory diagram schematically illustrating a fine dust concentration prediction system of the present invention.
FIG. 2 is a block diagram showing the configuration of a fine dust concentration prediction unit based on big data and artificial intelligence learning in the main server of FIG. 1.
3 is an example showing the fine dust concentration to a user terminal through the fine dust concentration prediction system of the present invention.

With reference to the accompanying drawings the fine dust concentration prediction system of the present invention will be described in detail below.

1 is an explanatory diagram schematically illustrating a fine dust concentration prediction system of the present invention.

A fine dust measuring device 310 equipped with a fine dust sensor (not shown) is installed in each of a plurality of divided regions within a predetermined area, and the fine dust measuring devices 310 in each of the plurality of divided regions are collectively referred to as It is referred to as the dust concentration detection unit 300. Each divided area has an identification code.

The fine dust measuring device 310 transmits the fine dust concentration signal detected through the fine dust sensor (not shown) to the main server 200. Here, the fine dust sensor may be a sensor to which the light scattering method is applied, and is a commercially available fine dust sensor. -PWM-01A model, etc. can be used.

The fine dust concentration signal detected by the fine dust sensor (not shown) of the fine dust measuring device 310 is transmitted to the main server 200 through the communication unit (not shown) of the fine dust measuring device 310, When transmitting to 200, the LoRa network, a dedicated Internet of Things (IoT) network built by SK Telecom, is used.

The user terminal 100 has a predetermined application program installed, and may be a user's smartphone, notebook, computer, PDA, or the like. The user terminal 100 may request the current fine dust concentration or predicted future fine dust concentration for each predetermined divided area to the main server 200, and the current fine dust concentration or the future is transmitted from the main server 200. The predicted fine dust concentration of is output.

The main server 200 receives the fine dust concentration signal received from the fine dust measuring devices 310 and stores it in the database of the main server 200, and uses this to perform big data pattern analysis. It predicts the dust concentration and transmits not only the current fine dust concentration for each segment but also the future fine dust concentration to the user's smartphone.

FIG. 2 is a block diagram showing the configuration of a fine dust concentration prediction unit based on big data and artificial intelligence learning in the main server of FIG. 1.

The fine dust concentration prediction unit based on big data and artificial intelligence learning, as a component included in the main server 100, uses big data technology to provide environmental information that affects the fine dust concentration including the fine dust concentration signal. Is collected and accumulated in real time, and based on this, the pattern of the fine dust concentration is inferred by the artificial intelligence learning method based on the artificial neural network (referred to as "artificial neural network" for convenience of explanation) to detect the pattern of fine dust concentration. It is implemented to be able to predict and prepare.

The fine dust concentration prediction unit based on big data and artificial intelligence learning includes a big data collection and classification system 210, an artificial neural network system 220 for extracting a fine dust concentration pattern, and a fine dust concentration prediction subsystem 230, and the like. .

The big data collection and classification system 210 is a means for collecting and classifying big data including the concentration of fine dust, and includes a big data collection module 212, a big data classification and processing module 215, and a big data storage unit ( 216).

The big data collection module 212 not only collects the fine dust concentration signal from the fine dust concentration detection unit 300, but also stores topographic information of a predetermined area and a distribution map of a divided area. In addition, although not shown in FIG. 1, the big data collection module 212 includes AWS (Automatic Weather System, automatic weather observation system) measurement information provided by the Meteorological Agency, that is, temperature, precipitation, wind direction, wind speed, humidity, atmospheric pressure, and solar radiation. , Sunlight-related information is received, and UM (Unified Model, Integrated Numerical Forecasting Model) weather information provided by the Meteorological Agency, that is, forecast information such as snow, rain, and air pollution is received.

The big data classification and processing module 215 classifies and processes the big data collected by the big data collection module 212. That is, big data can be classified into divided regions, by date (or by time).

The big data storage unit 216 stores big data processed by the big data classification and processing module 215.

The fine dust concentration pattern extraction artificial neural network system 220 includes information on the concentration of fine dust accumulated by each divided area, measurement information on an Automatic Weather System (AWS) provided by the Meteorological Administration, and a unified model (UM). Forecast model) After receiving big data of meteorological information from the big data collection and classification system 210 and learning it repeatedly, based on this learning, the pattern of fine dust concentration for each divided area is inferred and stored. Here, AWS measurement information and UM weather information provided by the Meteorological Agency are collectively referred to as'weather information' for convenience of explanation.

The fine dust concentration pattern extraction artificial neural network system 220 includes an artificial neural network input layer classification module 222, an artificial neural network-based learning module 225, and a fine dust concentration pattern database 226.

The artificial neural network input layer classification module 222 performs a classification operation for inputting the big data received from the big data storage unit 216 into the artificial neural network.

The artificial neural network-based learning module 225 is a means for extracting a fine dust concentration pattern using an artificial neural network.

The fine dust concentration pattern database 226 is a database that stores data on the fine dust concentration pattern extracted from the artificial neural network-based learning module 225.

The fine dust concentration prediction system 230 based on the fine dust concentration pattern is an artificial fine dust concentration pattern extraction in order to predict the fine dust concentration on a predetermined day (or a predetermined time of a predetermined day) of the divided area requested through the user terminal 100. Fine dust of a corresponding date (a predetermined month or predetermined time) using the fine dust concentration pattern of the divided area from the neural network system 220 and the fine dust concentration data of the divided area stored in the big data storage unit 216 It is a means for predicting the concentration in advance and transmitting the corresponding information to the user terminal 100 to make a forecast. The fine dust concentration prediction system 230 includes a fine dust concentration prediction module 232 and a fine dust concentration prediction module 235.

The fine dust concentration prediction module 232 uses a large data storage unit 216 to predict the fine dust concentration on a predetermined day (date) of the divided area requested through the user terminal 100, using a fine dust concentration prediction artificial neural network. ) And the data stored in the fine dust concentration pattern database 226, the fine dust concentration of the divided area of the requested day (or a predetermined time of a predetermined day) is predicted in advance.

Here, the fine dust concentration prediction module 232 uses the fine dust concentration prediction artificial neural network to extract the fine dust concentration based on the data stored in the big data storage unit 216 and the fine dust concentration pattern database 226. It is learned in advance.

The fine dust concentration prediction module 235 transmits the fine dust concentration received from the fine dust concentration prediction module 232 to the user terminal 100, and the fine dust concentration received from the fine dust concentration prediction module 232 is It is determined whether or not a preset reference value has been exceeded, and if it is exceeded, a message informing a dangerous state is transmitted to the user terminal 100.

Hereinafter, a method of driving a fine dust concentration prediction system will be schematically described with reference to FIGS. 1 and 2.

When a user requests fine dust concentration information on a predetermined day (date) of a predetermined divided area on the user terminal 100, the user terminal 100 provides an identification code and predetermined date information (month, day, time, etc.) of the predetermined divided area. The fine dust concentration prediction request information including the is transmitted to the main server 200.

The main server 200 receives the fine dust request information from the user terminal 100 by the user, and inputs the identification code and the predetermined date information of the predetermined segmented area as input data to the predicted fine dust concentration artificial neural network, and predicts the fine dust concentration. The fine dust information of the divided area of the predetermined period output from the artificial neural network is output to the user terminal 100. That is, the fine dust concentration prediction system 230 includes the fine dust concentration pattern of the divided region from the artificial neural network system 220 for extracting the fine dust concentration pattern, and the fine dust concentration data of the divided region stored in the big data storage unit 216. Is applied to the artificial neural network for predicting the concentration of fine dust to predict the concentration of fine dust at the corresponding date (a predetermined day or a predetermined time in a predetermined month).

The main server 200, that is, the fine dust concentration prediction module 235 transmits the fine dust concentration received from the fine dust concentration prediction module 232 to the user terminal 100.

The main server 200, that is, the fine dust concentration prediction module 235, determines whether the fine dust concentration received from the fine dust concentration prediction module 232 exceeds a preset reference value, and if it exceeds the user, a message indicating a dangerous state It transmits to the terminal 100.

3 is an example showing the fine dust concentration to a user terminal through the fine dust concentration prediction system of the present invention.

It shows the concentration of fine dust in each divided area, and shows the concentration of fine dust and other air quality information in the predetermined divided area.

As described above, although the present invention has been described by the limited embodiments and drawings, the present invention is not limited to the above embodiments, which is various modifications and variations from these descriptions to those of ordinary skill in the field to which the present invention belongs. Transformation is possible. Accordingly, the spirit of the present invention should be grasped only by the claims set forth below, and all equivalent or equivalent modifications thereof will be said to belong to the scope of the present invention.

100: user terminal 200: main server
210: Big data collection and classification subsystem 212: Big data collection module
215: big data classification and processing module 216: big data storage unit
220: artificial neural network learning subsystem 222: artificial neural network input layer classification module
225: artificial neural network-based learning module 226: fine dust concentration pattern database
230: fine dust concentration prediction subsystem 232: fine dust concentration prediction module
235: fine dust concentration forecast module 300: fine address concentration detection unit
310: fine dust measuring device

Claims (10)

A user terminal for transmitting fine dust concentration prediction request information including an identification code of a predetermined divided area and a predetermined date information to the main server in order to know the concentration of fine dust in a predetermined divided area of a predetermined date;
Prediction of fine dust concentration, inputting the identification code and predetermined date information of the divided area as input data into the artificial neural network, and transmitting the fine dust concentration information of the divided area of the predetermined date output from the fine dust concentration prediction artificial neural network to the user terminal. , Main server;
It characterized in that it comprises a, fine dust concentration prediction system. The method of claim 1,
A fine dust measuring device equipped with a fine dust sensor is mounted in each of the plurality of divided areas, and further includes a fine dust concentration detector that transmits fine dust concentration information detected by each fine dust sensor to the main server,
The main server forms big data by accumulating the received fine dust concentration information and meteorological information provided from the Meteorological Agency, and extracts the pattern of the fine dust concentration by applying the big data to the fine dust concentration pattern detection artificial neural network. Fine dust concentration prediction system. The method of claim 2, wherein the main server,
Fine dust concentration prediction system, characterized in that to extract the fine dust concentration information of the divided area of the corresponding date using the pattern and big data of the fine dust concentration from the artificial neural network. The method of claim 2,
The meteorological information, characterized in that the AWS (Automatic Weather System) measurement information and UM (Unified Model) meteorological information provided by the Meteorological Agency, a fine dust concentration prediction system. The method of claim 3, wherein the main server,
A big data collection and classification system that collects fine dust concentration and meteorological information, and classifies it by date of each divided area to form big data;
A fine dust concentration pattern extraction artificial neural network system for extracting a pattern of fine dust concentration by applying big data to a fine dust concentration pattern detection artificial neural network;
Fine dust concentration prediction system for extracting fine dust concentration information of a corresponding segmented area at a corresponding date by using a pattern of fine dust concentration and big data from an artificial neural network;
It characterized in that it comprises a, fine dust concentration prediction system. The method of claim 5, wherein the big data collection and classification system,
A big data collection module for collecting fine dust concentration information received from the fine dust concentration detection unit and meteorological information provided by the Meteorological Agency;
A big data classification and processing module that classifies and processes big data collected by the big data collection module;
A big data storage unit for storing big data processed by the big data classification and processing module;
It characterized in that it comprises a, fine dust concentration prediction system. The method of claim 6, wherein the fine dust concentration pattern extraction artificial neural network system,
An artificial neural network input layer classification module for performing a classification operation for applying the big data received from a big data storage unit to an artificial neural network extracting a fine dust concentration pattern;
A learning module based on an artificial neural network for extracting a fine dust concentration pattern using an artificial neural network for extracting a fine dust concentration pattern;
A fine dust concentration pattern database for storing data on the fine dust concentration pattern extracted from the artificial neural network-based learning module;
It characterized in that it comprises a, fine dust concentration prediction system. The method of claim 7, wherein the fine dust concentration prediction system,
Fine dust concentration prediction Using an artificial neural network, based on the data stored in the big data storage unit and the fine dust concentration pattern database, the fine dust concentration predicts the fine dust concentration in the divided area at the corresponding date of the fine dust concentration prediction request information. Prediction module;
The fine dust concentration forecast that transmits the fine dust concentration received from the fine dust concentration prediction module to the user terminal, determines whether the fine dust concentration exceeds a preset reference value, and transmits a message notifying the danger status to the user terminal if it exceeds module;
It characterized in that it comprises a, fine dust concentration prediction system. The method of claim 7,
The fine dust concentration pattern extraction artificial neural network is an artificial neural network that has been learned in advance to extract a pattern of fine dust concentration using the fine dust concentration information received from the fine dust concentration detection unit and the meteorological information provided by the Meteorological Agency, Fine dust concentration prediction system. The method of claim 9,
The artificial neural network for predicting fine dust concentration is an artificial neural network that has been learned in advance to output the fine dust concentration of each divided area according to the date using the data stored in the fine dust concentration pattern database and the data stored in the big data storage unit. Characterized by, fine dust concentration prediction system.

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