KR20120101952A - Processing system for temperature field of diffusion model using weather diagnostic model and processing method therefor - Google Patents

Abstract

PURPOSE: A system and a method for post-treating the temperature filed of a diffusion model by using a weather diagnostic model are provided to flexibly express the temperature field by re-analyzing result data of a three dimensional weather filed diagnosis model. CONSTITUTION: A system for post-treating the temperature filed of a diffusion model by using a weather diagnostic model includes a weather filed generating part(100), a topographical data generating part(200), and a temperature filed boundary generating part(300). The weather filed generating part generates a weather field by modeling an MM5 model. The topographical data generating part generates the topography of a wind filed by using the weather filed. The temperature filed boundary generating part generates a temperature filed by modeling a CALMET model based on the weather filed of the MM5 model and weather observation data. [Reference numerals] (100) Weather field generating part; (110) Topography generating module; (120) Horizontal interpolation module; (130) Vertical interpolation module; (140) Weather field generating module; (200) Topographical data generating part; (210) Coordinate converting module; (220) Topographical data generating module; (300) Temperature field boundary generating module; (310) Three dimensional temperature field generating module; (320) Two dimensional temperature value extracting module; (330) Maximum/minimum temperature field value calculating module; (340) Temperature field boundary generating module

Description

Temperature field post-treatment system and method of diffusion model using meteorological diagnostics model {PROCESSING SYSTEM FOR TEMPERATURE FIELD OF DIFFUSION MODEL USING WEATHER DIAGNOSTIC MODEL AND PROCESSING METHOD THEREFOR}

The present invention relates to a temperature field post-processing system and method of a diffusion model for reprocessing and expressing a temperature field extracted from a 3D meteorological field diagnostic model. The present invention relates to a temperature field post-treatment system and method for a diffusion model that flexibly expresses a temperature field as needed.

The MM5 / CALMET model is driven by a combination of the MM5 and CALMET models. It features multiple lattice structures, non-statics, four-dimensional data assimilation, and various physical options. The MM5 / CALMET model is also based on the regional forecasting system, RDAPS (Regional Data Assimilation and Prediction System), currently used by the Meteorological Agency. The CALMET model is a diagnostic model that generates hourly meteorological fields using the results of MM5, a weather model, in the 3D grid modeling area. In addition, two-dimensional data such as mixed altitude, surface characteristics, and diffusion characteristics are generated by using upper layer weather data, ground weather data, precipitation data, topographical data, and land use. Within the CALMET model is the CALPOST, a post-processing program for meteorological field results.

However, CALPOST alone is limited in expressing the result in a desired form according to the user's purpose.

It is an object of the present invention to provide a temperature field post-treatment system and method for a diffusion model which can express the result in a desired form according to the purpose of the user.

In order to achieve the above object, the present invention provides a meteorological field generation unit for generating a meteorological field by modeling the MM5 model, a terrain data generation unit for generating the terrain of the wind field with the meteorological field generated by the meteorological field generation unit, and The meteorological diagnostic model comprising a temperature field boundary generator for generating a temperature field by modeling the CALMET model as an input data of the MM5 model generated by the meteorological field generator and the surface and high-rise weather observation data. It provides a temperature field post-treatment system of the diffusion model used. The meteorological field generating unit may include a terrain generation module for generating terrain in a domain through a TERRAIN process, a horizontal interpolation module for horizontal interpolation of ground and registered pressure surface weather data of the MM5 model through a GEGRID process, and the registered pressure surface data. It includes a vertical interpolation module to vertical interpolation into the sigma coordinate system data of the vertical coordinate system of the MM5 model, and a meteorological field generation module that simulates the meteorological field of the desired time by numerically integrating the data analyzed in the vertical interpolation module . The weather field generated by the weather field generation module may be derived as a DEG file. The terrain data generation unit may include a coordinate system transformation module for converting the X-axis and Y-axis TM coordinate information of the grid in the domain from the DEG file into a latitude-longitude coordinate system, and the relatided latitude-longitude coordinate information in the domain in the coordinate system transformation module. And a terrain data generation module for generating corresponding terrain data using TOPO terrain information. The temperature field boundary generation unit may include a three-dimensional temperature field generation module configured to generate a three-dimensional temperature field through CALMET modeling using the weather field, the surface of the MM5 model generated by the meteorological field generator, and the high-rise weather observation data as input data; A two-dimensional temperature value extraction module for extracting a two-dimensional temperature value for a corresponding grid of a domain recorded after header information of the DEG file, and a two-dimensional temperature value extracted by the two-dimensional temperature value extraction module; A temperature field maximum / minimum value calculation module for setting a boundary range of a temperature field by calculating a value and a minimum value, and on a terrain data in a domain generated by the terrain data generation unit, 2 as a boundary range of the three-dimensional temperature field and the temperature field. It includes a temperature field boundary generation module for generating a boundary of the dimensional temperature field. The temperature field boundary generating module may include a temperature field boundary storage unit for storing the boundary of the two-dimensional temperature field generated on the terrain data.

In addition, the present invention is to model the MM5 model to generate a weather field, to generate a wind field topography with the weather field, and to model the CALMET model with the weather field, surface and high-rise weather observation data as input data And extracting a three-dimensional temperature field to generate a boundary of the temperature field, and providing a temperature field post-processing method of a diffusion model using a meteorological diagnostic model. Generating the meteorological field by modeling the MM5 model, generating the terrain in the domain through the TERRAIN process, horizontal interpolation of the ground and registered pressure surface weather data of the MM5 model through the GEGRID process, and the registration Vertical interpolation of the pressure-sensitive data into the sigma coordinate system data, which is the vertical coordinate system of the MM5 model through the INTERPF process; Numerically integrating the data to simulate the weather field at the time desired by the user. The generating of the wind field topography using the weather field may include converting the X-axis and Y-axis TM coordinate information for the lattice in the domain from the simulated weather field into a latitude-longitude coordinate system, and the domain from the simulated weather field. And converting the X-axis and Y-axis TM coordinate information for the lattice in the latitude-longitude coordinate system into the terrain data corresponding to the relatted latitude-longitude coordinate information in the domain using the TOPO terrain information. The CALMET model is modeled using the meteorological field, the surface and the high-rise weather observation data as input data, and the boundary of the temperature field is generated by extracting the three-dimensional temperature field. Generating a three-dimensional temperature field through the CALMET modeling using the input data, extracting the two-dimensional temperature value for the domain corresponding grid in the meteorological field, and the maximum and minimum values of the temperature field as the two-dimensional temperature value Calculating and setting a boundary range of the temperature field; and generating a boundary of the two-dimensional temperature field in the boundary range between the three-dimensional temperature field and the temperature field on the terrain data. And storing the boundary of the two-dimensional temperature field generated on the terrain data.

The present invention provides a temperature field post-processing system of a diffusion model capable of generating a boundary of a temperature field using a meteorological field generated through numerical integration, and displaying it on topographic data in a domain to express a result in a desired form according to a user's purpose. The method can be provided.

1 is a conceptual diagram of a temperature field post-processing system of a diffusion model using a meteorological diagnosis model according to the present invention.
2 to 5 are the results of the temperature field post-processing of the three-dimensional meteorological field diagnostic model using the temperature field post-processing system of the diffusion model using the meteorological diagnostic model according to the present invention.
Figure 6 is a flow chart of the temperature field post-processing method of the diffusion model using a meteorological diagnostic model according to the present invention.

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

It will be apparent to those skilled in the art that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, It is provided to let you know. Like reference numerals refer to like elements throughout.

1 is a conceptual diagram of a temperature field post-processing system of a diffusion model using a meteorological diagnosis model according to the present invention.

As shown in FIG. 1, the temperature field post-processing system of the diffusion model using the meteorological diagnosis model according to the present invention includes a meteorological field generator 100, a terrain data generator 200, and a temperature field boundary generator ( 300).

The meteorological field generator 100 generates a meteorological field by modeling the MM5 model. The weather field generator 100 includes a terrain generation module 110, a horizontal interpolation module 120, a vertical interpolation module 130, and a weather field generation module 140.

The terrain generation module 110 generates the terrain in the domain through the TERRAIN process. At this time, the TERRAIN process uses a temperature field post-processing program of a 3D meteorological field diagnostic model developed using IDL (Interactive Data Language). IDL is an efficient computer language for data processing and contour graphics for model results because it has efficient array data processing, convenient and powerful graphics, and includes a variety of libraries for scientists.

The horizontal interpolation module 120 is used for horizontal interpolation of the surface and atmospheric pressure surface data of the MM5 model, and is horizontally interpolated through the GEGRID process in the temperature field post-processing program of the above-described three-dimensional meteorological field diagnostic model. At this time, the horizontal grid map projection is supported by Mercator, Lambert Conformal, and Polar stereographic projection.

The vertical interpolation module 130 interpolates the registered pressure plane data into sigma coordinate system data, which is a vertical coordinate system of the MM5 model, through the INTERPF process.

The meteorological field generation module 140 is for modeling the MM5 model, and simulates a meteorological field of a desired time by numerically integrating data analyzed in the INTERPF process of the vertical interpolation module. At this time, the simulated weather field is derived as a DEG file.

The terrain data generator 200 generates a terrain of wind fields using a weather field generated by the weather field generator 100, that is, a DEG file. To this end, the terrain data generation unit 200 includes a coordinate system conversion module 210 and the terrain data generation module 220.

The coordinate system conversion module 210 converts the X-axis and Y-axis TM coordinate information for the lattice in the domain from the DEG file into the latitude and longitude coordinate system. Here, in the header of the DEG file, the number of grids of the domain and the coordinates of each edge of the lower left and upper right of the domain are recorded. Accordingly, the coordinate system conversion module 210 reads the header information from the DEG file and converts coordinate information about the grid in the domain from the TM coordinate system to the latitude and longitude coordinate system. In addition, all lattice in the domain from the transformed latitude and longitude coordinate system are relatted to latitude and longitude coordinates.

The terrain data generation module 220 generates terrain data corresponding to the relatted latitude and longitude coordinate information in the domain in the coordinate system transformation module 210 using the TOPO terrain information.

The temperature field boundary generating unit 300 is for generating a temperature field from the modeling result of the CALMET model, and includes a three-dimensional temperature field generating module 310, a two-dimensional temperature value extracting module 320, and a maximum / minimum temperature field. A calculation module 330 and a temperature field boundary generation module 340.

The three-dimensional temperature field generation module 310 is a three-dimensional temperature field through the CALMET modeling using the meteorological field, surface and high-rise weather observation data (AWS, SONDE) of the MM5 model generated by the meteorological field generator 100 as input data. Create In this case, the generated three-dimensional temperature field may be generated as a DEG file.

The two-dimensional temperature value extraction module 320 extracts the two-dimensional temperature value generated for the three-dimensional temperature field generated by the three-dimensional temperature field generation module 310, that is, the corresponding grid of the domain recorded after the header information of the DEG file. do.

The temperature field maximum / minimum value calculation module 330 calculates the maximum / minimum value of the temperature field by using the two-dimensional temperature value extracted by the two-dimensional temperature value extraction module and sets a contour range of the temperature field.

The temperature field boundary generation module 340 calculates a three-dimensional temperature field and a temperature field maximum / minimum value generated by the three-dimensional temperature field generation module 310 on the terrain data in the domain generated by the terrain data generation unit 200. A boundary of the two-dimensional temperature field is generated in the boundary range of the temperature field set at 330.

Meanwhile, the present invention may further include a temperature field boundary storage unit (not shown) that stores the boundary of the two-dimensional temperature field generated on the terrain data in the temperature field boundary generation module 340. In this case, the boundary of the two-dimensional temperature field generated on the terrain data stored in the temperature boundary storage unit may be stored as an image such as a JPG file.

Hereinafter, the experimental results of the temperature field post-treatment system of the diffusion model using the meteorological diagnosis model according to the present invention having the above-described structure will be briefly described.

2 to 5 are the results of the temperature field post-processing of the three-dimensional meteorological field diagnostic model using the temperature field post-processing system of the diffusion model using the weather diagnosis model according to the present invention.

Temperature field post-processing of the diffusion model using the meteorological diagnostic model according to the present invention through a 24-hour simulation (April 25, 2008 0000LST-April 25, 2008 2400LST) The system was applied. The domains had a horizontal lattice of 132 × 142, and the TM coordinates (X, Y) at the bottom left and top right were (214.50 km, -163.50 km) and (345.50 km, -22.50 km), respectively. As a result of performing the post-processing, it can be seen that the contour of the temperature field appears in a form suitable for the research purpose according to the level and color bar set by the user as shown in FIGS. 2 to 5.

As described above, the present invention generates the boundary of the temperature field with the meteorological field generated through numerical integration, and displays it on the terrain data in the domain to express the result in a desired form according to the user's purpose, the temperature of the diffusion model Enteric post-treatment systems can be provided.

Next, a temperature field post-processing method of a diffusion model using a meteorological diagnosis model according to the present invention will be described with reference to the accompanying drawings. Among the contents to be described later, the description overlapping with the description of the temperature field after-treatment system of the diffusion model using the meteorological diagnosis model according to the present invention will be omitted or briefly described.

6 is a flow chart of a temperature field post-processing method of a diffusion model using a meteorological diagnosis model according to the present invention.

In the post-processing method of the temperature field of the diffusion model using the meteorological diagnosis model according to the present invention, as illustrated in FIG. 6, a step S1 of generating a weather field, a step S2 of generating terrain data, and a temperature field Generating a boundary (S3).

Generating the weather field (S1) generates a weather field by performing modeling of the MM5 model. Generating the weather field (S1) includes the step of generating the terrain (S1-1), performing the horizontal interpolation (S1-2), performing the vertical interpolation (S1-3), and Step S1-4 is simulated.

In the generating of the terrain (S1-1), the terrain in the domain is generated through the TERRAIN process. That is, the terrain in the domain to simulate the weather field is generated using the temperature field post-processing program of the 3D weather field diagnostic model.

In the step S1-2, horizontal interpolation is interpolated horizontally through the GEGRID process in the above-described temperature field post-processing program of the three-dimensional meteorological field diagnostic model, and horizontally interpolates the ground and registered pressure surface weather data of the MM5 model. .

In step S1-3, vertical interpolation is performed by interpolating vertical pressure data into sigma coordinate system data, which is a vertical coordinate system of the MM5 model.

Simulating the weather field (S1-4) numerically integrates the data analyzed in the INTERPF process of performing vertical interpolation (S1-3) to simulate the weather field of the desired time. In this case, the simulated weather field may be derived as a DEG file.

The generating of the terrain data (S2) generates the terrain of the wind field as the weather field generated in the step S1-4 simulating the weather field. To this end, the generating of the terrain data (S2) includes converting the coordinate system (S2-1), and generating the terrain data with the TOPO terrain information (S2-2).

In the step S2-1 of converting the coordinate system, the header information is read from the DEG file derived in step S1-4, which simulates the weather field, and the coordinate information of the grid in the domain is converted from the TM coordinate system to the latitude-longitude coordinate system. . In addition, all lattice in the domain from the transformed latitude and longitude coordinate system are relatted to latitude and longitude coordinates.

In the generating of the terrain data using the TOPO terrain information (S2-2), the terrain data corresponding to the relatted latitude and longitude coordinate information in the domain is generated using the TOPO terrain information in the transforming coordinate system (S2-1). .

Generating the temperature field boundary (S3) generates a temperature field from the modeling results of the CALMET model. To this end, the step S3 of generating a temperature field boundary may include generating a three-dimensional temperature field (S3-1), extracting a two-dimensional temperature value (S3-2), and calculating a maximum / minimum value of the temperature field. Step S3-3, and generating the temperature field by generating the boundary of the temperature field (S3-4).

Generating the three-dimensional temperature field (S3-1) is a CALMET modeling using the weather field and the surface and high-rise weather observation data (AWS, SONDE) of the MM5 model generated in the step (S1) generating the meteorological field as input data. Create a three-dimensional temperature field through. In this case, the generated three-dimensional temperature field may be generated as a DEG file.

Extracting the two-dimensional temperature value (S3-2) is a three-dimensional temperature field generated in generating the three-dimensional temperature field (S3-1), that is, the grid of the domain recorded after the header information of the DEG file. Extract the two-dimensional temperature values for.

The step S3-3 of calculating the maximum / minimum value of the temperature field is a two-dimensional temperature value extracted in the step S3-2 of extracting the two-dimensional temperature value to calculate the maximum / minimum value of the temperature field. Set the range.

Generating the temperature field by generating the boundary of the temperature field (S3-4) is a step of generating a three-dimensional temperature field on the terrain data in the domain generated in the step of generating the terrain data (S3-1) The boundary of the two-dimensional temperature field is generated in the boundary range of the three-dimensional temperature field generated in the step S and the temperature field set in the step S3-3 of calculating the maximum / minimum value of the temperature field.

On the other hand, the present invention may further comprise the step of storing the boundary of the two-dimensional temperature field generated on the terrain data in the step (S3-4) of generating the temperature field by generating the boundary of the temperature field.

As described above, the present invention generates the boundary of the temperature field with the meteorological field generated through numerical integration, and displays it on the terrain data in the domain to express the result in a desired form according to the user's purpose, the temperature of the diffusion model Intestinal post-treatment methods can be provided.

Although described above with reference to the drawings and embodiments, those skilled in the art can be variously modified and changed within the scope of the invention without departing from the spirit of the invention described in the claims below. I can understand.

100: meteorological field generator 110: terrain generation module
120: horizontal interpolation module 130: vertical interpolation module
140: meteorological field generation module 200: terrain data generation unit
210: coordinate system conversion module 220: terrain data generation module
300: temperature field boundary generation unit 310: three-dimensional temperature field generation module
320: two-dimensional temperature value extraction module
330: temperature field maximum / minimum value calculation module
340: temperature field boundary generation module

Claims (15)

A meteorological field generator for generating a meteorological field by modeling an MM5 model;
A terrain data generator for generating a terrain of a wind field as a meteorological field generated by the meteorological field generator, and
The meteorological diagnostic model comprising a temperature field boundary generator for generating a temperature field by modeling the CALMET model as an input data of the MM5 model generated by the meteorological field generator and the surface and high-rise weather observation data. Temperature field post-treatment system of the diffusion model. The method according to claim 1,
The meteorological field generator,
A terrain generation module that generates terrain in the domain through the TERRAIN process,
A horizontal interpolation module for horizontal interpolation of the ground and registered pressure surface weather data of the MM5 model through a GEGRID process;
A vertical interpolation module for vertically interpolating the registered pressure plane data into sigma coordinate system data, which is a vertical coordinate system of the MM5 model; and
And a meteorological field generation module that simulates a meteorological field of a user's desired time by numerically integrating the data analyzed by the vertical interpolation module. The method according to claim 2,
The temperature field post-processing system of the diffusion model using the weather diagnosis model, characterized in that derived from the weather field generation module DEG file. The method according to claim 1 or 2,
The terrain data generation unit,
A coordinate system transformation module for converting the X-axis and Y-axis TM coordinate information of the lattice in the domain from the meteorological field into a latitude-longitude coordinate system; and
After the temperature field of the diffusion model using the meteorological diagnostic model, the coordinate system conversion module comprises a terrain data generation module for generating terrain data corresponding to the relatted latitude and longitude coordinate information in the domain using the TOPO terrain information Processing system. The method of claim 4,
The temperature field boundary generator,
A three-dimensional temperature field generation module for generating a three-dimensional temperature field through CALMET modeling using the meteorological field, the surface of the MM5 model generated by the meteorological field generator, and the high-rise meteorological observation data as input data;
A two-dimensional temperature value extraction module for extracting a two-dimensional temperature value for a corresponding lattice of the domain from the gas field;
A temperature field maximum / minimum value calculation module configured to set the boundary range of the temperature field by calculating the maximum value and the minimum value of the temperature field with the two-dimensional temperature value extracted by the two-dimensional temperature value extraction module, and
A meteorological diagnosis model comprising a temperature field boundary generation module for generating a boundary of a two-dimensional temperature field in a boundary range between the three-dimensional temperature field and the temperature field on the terrain data generated in the terrain data generation unit. Field post-treatment system of diffusion model using The method according to claim 5,
And a temperature field boundary storage unit configured to store the boundary of the two-dimensional temperature field generated on the terrain data in the temperature field boundary generation module. The method according to claim 1,
The temperature field boundary generator,
A three-dimensional temperature field generation module for generating a three-dimensional temperature field through CALMET modeling using the meteorological field, the surface of the MM5 model generated by the meteorological field generator, and the high-rise meteorological observation data as input data;
A two-dimensional temperature value extraction module for extracting a two-dimensional temperature value for a corresponding lattice of the domain from the gas field;
A temperature field maximum / minimum value calculation module configured to set the boundary range of the temperature field by calculating the maximum value and the minimum value of the temperature field with the two-dimensional temperature value extracted by the two-dimensional temperature value extraction module, and
A meteorological diagnosis model comprising a temperature field boundary generation module for generating a boundary of a two-dimensional temperature field in a boundary range between the three-dimensional temperature field and the temperature field on the terrain data generated in the terrain data generation unit. Field post-treatment system of diffusion model using The method of claim 7,
And a temperature field boundary storage unit configured to store the boundary of the two-dimensional temperature field generated on the terrain data in the temperature field boundary generation module. Modeling the MM5 model to generate a weather field;
Generating a terrain of a wind field into the weather field, and
Modeling a CALMET model as input data using the meteorological field, the surface and the high-level meteorological observation data, and extracting a three-dimensional temperature field to generate a boundary of the temperature field, wherein the temperature of the diffusion model using the meteorological diagnostic model is included. Post-treatment method. The method according to claim 9,
Generating the weather field by modeling the MM5 model,
Creating terrain in the domain through the TERRAIN process,
Horizontal interpolation of the above-mentioned ground and atmospheric pressure surface data of the MM5 model through a GEGRID process;
Vertical interpolation of the registered pressure plane data into sigma coordinate system data which is a vertical coordinate system of the MM5 model through an INTERPF process, and
Vertical interpolation of the registered pressure plane data into the sigma coordinate system data, which is a vertical coordinate system of the MM5 model; Post-processing of temperature field of diffusion model using meteorological diagnosis model. The method according to claim 9 or 10,
Generating the terrain of the wind field in the weather field,
Converting the X-axis and Y-axis TM coordinate information for the lattice in the domain from the meteorological field into a latitude and longitude coordinate system, and
Converting the X-axis and Y-axis TM coordinate information of the lattice in the domain from the meteorological field into a latitude-longitude coordinate system; generating topographic data corresponding to the relatted latitude-longitude coordinate information in the domain using TOPO terrain information Temperature field post-processing method of the diffusion model using a meteorological diagnostic model comprising the step. The method of claim 11,
The CALMET model is modeled using the weather field, the surface and the high-level weather observation data as input data, and the boundary of the temperature field is generated by extracting a three-dimensional temperature field.
Generating a three-dimensional temperature field through CALMET modeling using the meteorological field, the surface of the MM5 model, and the high-rise weather observation data as input data;
Extracting a two-dimensional temperature value for a domain corresponding grating in the gas field;
Calculating a maximum value and a minimum value of the temperature field using the two-dimensional temperature value to set a boundary range of the temperature field; and
And generating a boundary between the three-dimensional temperature field and the two-dimensional temperature field on the topographical data based on a boundary between the three-dimensional temperature field and the temperature field. The method of claim 12,
And storing the boundary of the two-dimensional temperature field generated on the terrain data. The method according to claim 9,
The CALMET model is modeled using the weather field, the surface and the high-level weather observation data as input data, and the boundary of the temperature field is generated by extracting a three-dimensional temperature field.
Generating a three-dimensional temperature field through CALMET modeling using the meteorological field, the surface of the MM5 model, and the high-rise weather observation data as input data;
Extracting a two-dimensional temperature value for a domain corresponding grating in the gas field;
Calculating a maximum value and a minimum value of the temperature field using the two-dimensional temperature value to set a boundary range of the temperature field; and
And generating a boundary between the three-dimensional temperature field and the two-dimensional temperature field on the topographical data based on a boundary between the three-dimensional temperature field and the temperature field. The method according to claim 14,
And storing the boundary of the two-dimensional temperature field generated on the terrain data.

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