WO2012036368A1

WO2012036368A1 - System for monitoring rainfall and water level in real-time and monitoring method using same

Info

Publication number: WO2012036368A1
Application number: PCT/KR2011/003963
Authority: WO
Inventors: 차영민; 장기호; 차주완; 양하영; 정진임; 최영진
Original assignee: 대한민국(기상청장)
Priority date: 2010-09-13
Filing date: 2011-05-31
Publication date: 2012-03-22
Also published as: KR101219506B1; KR20120027633A

Abstract

The present invention relates to a system for simultaneously monitoring rainfall and the resulting water level of a dam or reservoir in real-time. In more detail, the real-time simultaneous monitoring system includes: a weather information receiving processing unit for receiving rainfall data (e.g., converted rainfall data from a weather radar) of an observation target area and water level data of a river and a dam in an observation target area from an outdoor Automatic Weather System (AWS), an Automated Synoptic Observing System (ASOS), a weather radar, and a hydrological observation system of a flood control station through wired communication; a weather information processing unit for converting the received data from the weather information receiving processing unit into a processible format through a programming language to process the rainfall data and water level data treated through a graphic program; a database unit for storing the data, which are processed by the weather information processing unit, as an image file; and a display unit for displaying a result processed by the weather information processing unit. According to the present invention, live information on the rainfall of an observation target area and the water level change of a dam or river according to the rainfall are provided simultaneously in real-time, so that accurate weather prediction and flood forecasts may be provided.

Description

Rainfall and water level real-time monitoring system and monitoring method using the same

The present invention relates to a system and a display method for simultaneously monitoring in real time the rainfall of the dams and rivers and the resulting water level.

Due to climate change, the damages caused by floods are increasing not only in the world but also in Korea, and the damages of natural disasters caused by land development are also increasing. In order to minimize the damage and damage caused by the recurring floods, high-risk areas should be identified and managed to minimize the damage to life and property. To this end, local residents should be informed of the characteristics of the area, and a rapid disaster response that provides details of evacuation routes, evacuation sites, and support for medicines and food and critical rescue equipment in the event of a flood.

As part of the rapid response to the damage caused by the flood, the water level is observed and displayed in real time. However, immediate response to flood damage using real-time display of water levels is preliminary. Floods begin with rainfall, and rainfall is a good source of information for future flood changes and floods.

Therefore, by looking at rainfall and water level at the same time, it is possible to accurately and efficiently analyze and predict the effect of rainfall on future water level fluctuations. On the other hand, due to the river maintenance project including the four major river development projects, information on rainfall and the water level of dams and beams is required. Therefore, there is a need for a simultaneous real-time monitoring system of rainfall and water level, which can simultaneously display rainfall and water levels in real time, so that the trends can be integrated.

The present invention has been made to solve the above-described problems, the object of the present invention is to provide accurate and efficient torrential rain and flood by providing simultaneous presentation information on the rainfall of the observed area and the resulting change in the dam and river water level in real time It relates to techniques that can implement forecasts.

As a means for solving the above problems, the present invention is the rainfall data of the observation target area from the meteorological office automatic meteorological observation equipment (AWS), synoptic weather observation equipment (ASOS), weather radar and flood control station hydrological observation equipment Rainfall data), meteorological information receiving processing unit for receiving water level data of rivers and dams through wire communication; A weather information processing unit for processing rainfall and water level data for processing the data received by the weather information receiving unit into a form that can be processed by a graphic program; A database unit for storing the data processed by the weather information processing unit as an image file; It is possible to provide a real-time simultaneous monitoring system of rainfall and water level, including a display unit for displaying the results processed by the weather information processing unit.

In addition, the meteorological information processing unit according to the present invention, by matching the first color index divided according to the input rainfall data value to display at the observation point of the rainfall, the water level on the map presented by the display unit, the input water level The data may be processed to be displayed on the observation point of the water level presented by the display unit by matching the second color indicator with a filling technique according to the water level percentile value.

In addition, the first color indicator is implemented as a polygonal shape divided into different colors for each section according to the rainfall data value, the second color indicator is a water level percentile of the stream according to the water level percentile value is a rectangular, dam The water level percentile can be implemented as a real-time simultaneous monitoring system of rainfall and water level, which is implemented in such a way that the inverse isosceles trapezoidal figure is filled with colors.

By using the real-time monitoring system of rainfall and water level according to the present invention described above, it is possible to simultaneously check the water level of rainfall and dam or river in the following order.

Specifically, rainfall data of the area to be observed from the external automatic weather station (AWS), automatic synoptic observation system (ASOS), weather radar, flood control station hydrological observation equipment (weather radar is equivalent to rainfall) Data), step 1 for inputting the water level data of the rivers and dams in the observed area; Step 2 of processing the received rainfall data, water level data in the form of data that can be processed in a programming language; A three step of processing the processed rainfall data and water level data into numerical rainfall data values and water level percentile values using a graphic program; 4 steps of matching the processed rainfall data value and the water level percentile value with a color indicator value to display and display on a map; 5 steps to save the expressed data in the database; And displaying the stored data on the display unit in 6 steps.

In particular, in this case, the fourth step is to match the figure of the different colors according to the input rainfall data value, the water level percentile is a filling method according to the water level percentile rank, the ratio of the percentile to the rectangular or inverse isosceles trapezoid shape It may be implemented in such a way that the color corresponding to the.

According to the present invention, it is possible to realize accurate weather forecasting and flood forecasting by simultaneously providing real-time information on rainfall in the target area and fluctuations in water levels of dams and rivers accordingly.

1 schematically illustrates a configuration of a monitoring system according to the present invention.

2 to 4 are flowcharts illustrating a monitoring process according to the present invention.

5 shows a point for observing rainfall of the ASOS and AWS points of the Meteorological Agency.

Figure 6 shows a topographical map showing the water level observation and the points of dams and beams.

7 to 12 show real-time water level and rainfall information for each of the four river basins from which live information displayed on the display unit of the present monitoring system is derived.

Hereinafter, with reference to the accompanying drawings will be described in detail the configuration and operation according to the present invention. In the description with reference to the accompanying drawings, the same components are given the same reference numerals regardless of the reference numerals, and duplicate description thereof will be omitted. Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another.

The present invention is to provide a system and method for efficiently displaying and real-time processing of the rainfall and the resulting water level fluctuations when the rainfall occurs in the dams and beams of the observed region of the four major river basins nationwide do.

1 is a schematic diagram of a real-time monitoring system of rainfall and water level according to the present invention.

Referring to the drawings, the monitoring system according to the present invention, the meteorological office automatic weather observation equipment (AWS; 110), longitudinal weather observation equipment (ASOS; 120), weather radar 130 and flood control station hydrological observation equipment 140 Rainfall data of the observed area from the weather radar (equivalent radar data), weather information receiver 210 receives the water level data of rivers and dams in the observed area through wired communication, data received from the weather information receiver Is processed into a form that can be processed in a programming language, the weather information processing unit 220 for displaying the rainfall data, water level data processed using a graphic program, the database unit for storing the data processed by the weather information processing processor as an image file 230, the display unit 240 displaying a result processed by the weather information processing unit may be configured.

The operation of the configuration of the monitoring system according to the present invention described above will be described with reference to FIGS. 2 to 4 are flowcharts illustrating a monitoring process according to the present invention.

First, the meteorological information receiving processor 210 detects a target area from an automatic meteorological observation equipment (AWS) 110, a meteorological observation equipment (ASOS) 120, a weather radar 130, and a flood control station hydrological observation equipment (140). Rainfall data (e.g. weather radar data) will be received, and river level data on the area to be observed and dam level data will be received via wired communication. In addition, by determining the existence of the received data at regular intervals, if there is no received data, the process of checking whether the data is received again after stopping for a predetermined time is repeated.

Subsequently, when the meteorological information receiving processor 210 receives rainfall data of the observation target region, water level data of the river and the dam of the observation target region, the weather information processing processor 220 uses the received data using a programming language. Processed rainfall data and water level data are processed using graphic program. The processed data is output as video data and stored in the database.

Processing of data is processed in the form that can be processed in programming language, and processing of data is processed through the following process according to each information using graphic program.

Referring to FIG. 3, first of all, when rainfall data is input, it is displayed in a polygonal shape of different colors distinguished according to the input rainfall data value. In detail, the first color index is classified according to the input rainfall data value and displayed at the observation point of the rainfall level on the map presented by the display unit.

When the water level data is input, the water level percentile value is calculated, and then the rank is determined according to the size of the percentile, and the second color index is matched by the filling method according to the water level percentile rank. In the present embodiment, the input water level data is matched with a second color indicator by a peeling technique according to the water level percentile level and displayed on the observation point of the water level presented by the display unit according to the water level percentile value. According to the water level percentile value, the water level percentile of the stream is rectangular, and the water level percentile of the dam can be implemented in such a manner that colors are filled in an inverse isosceles trapezoid figure. The plotted image is then stored as an image file.

The calculation method of the water level percentile is as follows.

Water level (%) = (water level observation data of rivers and dams / flood control water level) × 100

River Water Percentile = {(Current Level-Zero Elevation) / (Planned Flood Level-Zero Elevation)} × 100

Dam Water Percentile = {(Presence-Low) / (Plan Flood-Low)} × 100

(However, the low water level is the lowest water level used in the operation of a normal reservoir, which means that the river level does not fall more than 275 days throughout the year. The planned flood level means the water level corresponding to the design criteria in the pulp work.) Elevation means the reference elevation adopted as a reference by a particular station.)

4 illustrates the above-described filling technique of the water level percentile.

The water level percentile of the river can be represented by a rectangle, and the water level percentile of the dam can be represented by an inverse isosceles trapezoidal figure. It can be implemented in a way that is gradually filled with color. Of course, the figure used can be variously modified in addition to.

One of the characteristics of the present invention implemented by the real-time monitoring system of rainfall and water level and the monitoring method using the same is that the rainfall and water level processing data of the target region to be observed can be simultaneously displayed, both domestically and globally. Simultaneous expression of rainfall and water level is not shown. Simultaneous display of rainfall and water levels implemented by the system according to the present invention enables the implementation of very efficient utilization in accurate weather forecasting and flood forecasting.

In particular, in the case of non-skilled person, the accurate determination of the location of the rainfall and the water level observation point is dropped, and when the rainfall information and the water level information are displayed separately, it is difficult to determine the influence on the fluctuation of the water level according to the rainfall. When the rainfall and the water level are expressed at once by using the monitoring system according to the system, the change of the water level according to the rainfall is provided at once and related to provide the information that can be predicted. In particular, the water level filling technique in the present invention can be more helpful in preventing the confusion of judgment that can be brought about when using indicators similar to the various color indicators of rainfall and facilitate the accurate analysis.

FIG. 5 illustrates a point for observing rainfall of the ASOS and AWS points of the Meteorological Agency, and FIG. 6 shows a topographical map showing water level observation and points of dams and beams. For example, the observation point may be largely divided into information of the Han River, Nakdong River, Geum River, Yeongsan River & Sumjin River basin, as shown in FIG. 7.

8 to 12 show real-time water level and rainfall information for each of the four river basins from which live information displayed on the display unit of the present monitoring system is derived.

In the detailed description of the present invention as described above, specific embodiments have been described. However, many modifications are possible without departing from the scope of the invention. The technical spirit of the present invention should not be limited to the described embodiments of the present invention, but should be determined not only by the claims, but also by those equivalent to the claims.

Claims

Rainfall data of the area to be observed (weather rainfall data in terms of weather radar) from the Meteorological Agency automatic weather observation equipment (AWS), longitudinal weather observation equipment (ASOS), weather radar, flood control stations Weather information receiving unit for receiving the data via wired communication;

A meteorological information processing unit for processing the data received by the meteorological information receiving unit into a processable form using a programming language and processing the rainfall data and the water level data processed using a graphic program;

A database unit for storing the data processed by the weather information processing unit as an image file;

A display unit which displays a result processed by the weather information processing unit;

Real-time simultaneous monitoring system of rainfall and water level, including.
The method according to claim 1,

The meteorological information processing unit,

Matches the first color indicators classified according to the input rainfall data values and displays them at the observation points of the rainfall and the water level on the map presented by the display unit.

The input water level data is processed to be displayed on the observation field of the water level presented by the display unit by matching with the second color index by the filling technique according to the water level percentile level according to the water level percentile value. Monitoring system.
The method according to claim 2,

The first color indicator is implemented in a polygonal shape divided into different colors according to the rainfall data value,

The second color indicator is a real-time monitoring system for rainfall and water level, which is implemented in such a way that the water level percentile of the stream is rectangular, and the water level percentile of the dam is filled with inverse isosceles trapezoids according to the water level percentile value.
The method according to claim 3,

The rainfall and water level real-time monitoring system,

Rainfall and water level real-time monitoring system, characterized in that the display is implemented in a way to simultaneously display the rainfall and water level processing data.
Rainfall data of the area to be observed (weather rainfall data in terms of weather radar) from the Meteorological Agency automatic weather observation equipment (AWS), longitudinal weather observation equipment (ASOS), weather radar, flood control stations Step 1 to receive data;

Processing the received rainfall data and the water level data in a state capable of processing using a programming language;

A three step of processing the processed rainfall data and water level data into numerical rainfall data values and water level percentile values using a graphic program;

4 steps of matching the numerical rainfall data value or the water level percentile value with a color indicator value to display and display on a map;

5 steps to save the expressed data in the database;

Displaying the stored data on a display unit;

Real-time monitoring method of rainfall and water level, including.
The method according to claim 5,

Step 4 and 6,

A method for real-time monitoring of rainfall and water level, which is implemented by simultaneously displaying rainfall and water level processing data.
The method according to claim 6,

The six steps,

Match the shapes of different colors according to the rainfall data input,

The water level percentile value is a peeling technique according to the water level percentile class, and the real-time simultaneous monitoring of rainfall and water level, which is a step in which a color corresponding to the percentage of the percentile is filled in a rectangular or inverse isosceles trapezoid figure.