KR101700648B1 - System for displaying carbon emission on the region planing model - Google Patents

Abstract

The carbon emission display system for the regional planning model of the present invention includes a scenario DB unit storing a plurality of scenario data including the target area identification information, zone identification information for a zone, road identification information, and element data; An extracting unit for extracting the zone identification information, the road identification information, and the element data included in the selected scenario data when the specific scenario data is selected from the plurality of scenario data; A calculation unit for calculating a carbon emission amount for the zone and the road using the extracted zone identification information, road identification information, and element data; A GIS information storage unit for storing GIS information mapped to the target area identification information, the zone identification information, and the road identification information, respectively; A GIS extracting unit for extracting GIS information corresponding to the zone and the road identification information in which the carbon emission amount is calculated; And a rendering GIS combining the extracted carbon emission information with the extracted GIS information, wherein the rendering GIS is configured to display the rendering GIS according to the calculated classification of the carbon emission amount according to the plurality of classification display classified information according to the size of the carbon emission amount. And an expression control unit for expressing the carbon emission amount in a differential manner.

Description

BACKGROUND OF THE INVENTION Field of the Invention [0001] The present invention relates to a carbon emission display system for a regional planning model,

The present invention relates to a system for expressing carbon emissions and the like. More specifically, the present invention relates to a system for expressing carbon emissions (environmental emissions) calculated by linking urban space / local space and traffic prediction data based on scenario data of a regional planning model By effectively integrating with GIS-based data and presenting it through a user-oriented GUI environment, it will provide visibility and easier and more accurate data infrastructure for follow-up work such as confirmation, evaluation, This is about a carbon emission display system for a regional planning model.

Recently, the issue of eco-friendliness has become an important issue for the whole society as a part of international cooperation for future global environment and issues of qualitative environment such as health, beyond merely a specific interest field.

For this reason, various efforts are being made by governments and public institutions to reduce environmental emissions such as carbon emissions. In planning regional development models such as urban, road and regional development, The model is applied to model the urban or regional space with environmental emission reduction.

In this connection, in the related arts including Korean Registered Patent No. 1012834, there is disclosed a method of estimating and calculating the amount of carbon using various factors, but since these methods correspond to arithmetic results of a large number of data, It is possible to say that there is an inherent limitation that is limited to the utilization of the human being.

Furthermore, these conventional methods are comparable to the numerical data from the viewpoint of establishing the city plan, and thus the visibility is remarkably low not only from a microscopic point of view but also from a macro point of view, There is a problem that the organic interlocking due to the change of the area to be checked or evaluated is almost impossible and the utilization is extremely limited.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to maximize the visibility by associating the calculated carbon emission amount with the GIS data and expressing the carbon emission amount by the visual difference method The present invention provides a system that can more easily and accurately confirm identification of a display area through organic combination with GIS data.

Other objects and advantages of the present invention will become apparent from the following description, and it will be apparent from the description of the embodiments of the present invention. Further, the objects and advantages of the present invention can be realized by a combination of the constitution shown in the claims and the constitution thereof.

In order to achieve the above object, a carbon emission display system for a regional planning model of the present invention is a scenario data for a development model of a target area, the target area identification information, the plurality of zones zone identification information, road identification information located between the zone and the zone, and element data on changes in land, population, building or traffic volume based on the zone and the road, are stored in a scenario DB section; An extracting unit for extracting the zone identification information, the road identification information, and the element data included in the selected scenario data when the specific scenario data is selected from the plurality of scenario data; A calculation unit for calculating a carbon emission amount for the zone and the road using the extracted zone identification information, road identification information, and element data; A GIS information storage unit storing GIS information mapped to the target area identification information, the zone identification information, and the road identification information, respectively; A GIS extracting unit for extracting GIS information corresponding to the zone and the road identification information in which the carbon emission amount is calculated; And a rendering GIS combining the extracted carbon emission information with the extracted GIS information, wherein the rendering GIS is configured to display the rendering GIS according to the calculated classification of the carbon emission amount according to the plurality of classification display classified information according to the size of the carbon emission amount. And an expression control unit for expressing the carbon emission amount in a differential manner.

In addition, the present invention may further include a level information input unit for receiving level information, which is information about a zoom of a view displayed on the screen display means, from the user, and in this case, If the input level information corresponds to reduction, a plurality of zones are integrated into one display unit area, and the carbon emission amount of the display unit area is calculated by the following equation, and then the rendering GIS is displayed do.

Where P is the total area of n zones, N is the number of zones to be merged, P _n is the area of the n-th zone, and Z _n is the carbon emissions of the n-th zone .

In addition, the display control unit of the present invention displays the calculated carbon emission amount by applying a differential color to each calculated classification of the carbon emission amount, and when the road is located in the zone, a color corresponding to the carbon emission amount of the road And controls to express the color gradually changing to the color corresponding to the carbon emission amount of the zone based on the color displayed on the road.

In order to implement the preferred embodiment, the present invention provides a CAI receiving apparatus comprising: a CAI receiving unit for communicating with a weather observation server and receiving a plurality of observation location information on the observation point and corresponding integrated air environment index (CAI) information; And a CAI region generation unit for calculating an intermediate position between the observed position information and generating a line connecting the calculated intermediate positions to generate a plurality of CAI display regions. In this case, The control unit may display the CAI information of the observation point existing in the generated CAI display area as CAI information of the corresponding CAI display area and display it in a different color according to the level of the CAI information.

If the plurality of CAI display areas are set in the zone, the display controller of the present invention displays the CAI information of the corresponding zone, calculates the CAI information of the corresponding zone according to the following equation, May be configured to display the CAI information in a differential color corresponding to the rating.

R is the total area of the corresponding zone, R _n is the area occupied by the n-th CAI display area in the zone, and C _n is the area occupied by the n-th CAI display area in the corresponding zone. In this equation, B is the CAI information of the zone, N is the total number of CAI- Is the CAI information of the n-th CAI display area.

The present invention may further comprise a vertex generation unit for extracting a plurality of vertex information constituting the zone and generating vertex assembly information which is a group composed of the plurality of vertex information. In this case, The display control unit displays the calculated carbon emission amount by applying a differential color to each of the classes corresponding to the calculated carbon emission amount, and outputs the display area information, which is a region in which a color corresponding to the corresponding carbon emission amount is displayed, to the vertex assembly And when the display view of the rendering GIS is rotated or enlarged, the relative rotation or enlargement processing of the position coordinate information of each vertex included in the vertex assembly information corresponding to the display area information, Display of the color of the zone and the color corresponding to the carbon emission of the zone Is controlled so that the synchronization area.

The carbon emission display system for the regional planning model according to the present invention can easily and conveniently provide the accurate carbon dioxide emission to the zone, which is a zone or a unit display area, by organically combining the calculated carbon emission with the corresponding GIS information And can maximize the visibility of carbon emissions.

In addition, the system according to the preferred embodiment of the present invention implements a user-oriented interface environment for an expression view so that the display area of carbon emission amount is organically changed in enlargement, reduction, rotation, and the like of an expression view , And a more user-oriented GUI environment can be implemented.

Further, according to another preferred embodiment of the present invention, the carbon emission amount is expressed in a differential color, and vertex information of the displayed area is independently generated and utilized, It is possible to provide infra data and the display processing can be selectively applied according to the user's selection of the display view, so that the display system more optimized for the user interface environment can be implemented.

BRIEF DESCRIPTION OF THE DRAWINGS The accompanying drawings, which are incorporated in and constitute a part of the specification, illustrate preferred embodiments of the invention and, together with the detailed description of the invention given below, serve to better understand the technical idea of the invention, And shall not be construed as limited to such matters.
BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram generally showing a carbon emission display system and related configuration for a regional planning model according to a preferred embodiment of the present invention;
2 is a block diagram showing a detailed configuration of a carbon emission display system for a regional planning model according to a preferred embodiment of the present invention;
FIG. 3 is a flowchart illustrating a method of displaying a carbon emission amount according to a preferred embodiment of the present invention.
FIG. 4 is a flowchart illustrating a method of displaying a carbon emission amount according to another preferred embodiment of the present invention. FIG.
FIG. 5 illustrates a preferred embodiment of the present invention in which carbon emissions are expressed in different ways for each zone of the subject area,
Figure 6 illustrates a preferred embodiment of the present invention in which carbon emissions are expressed when a plurality of zones are integrated;
FIG. 7 illustrates a preferred embodiment of the present invention that integrally exposes zones and zones of view for roads; FIG.
8 is a diagram showing a preferred embodiment of the present invention for displaying CAI in the zone of the zone.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to this, terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms, and the inventor should appropriately interpret the concepts of the terms appropriately It should be construed in accordance with the meaning and concept consistent with the technical idea of the present invention based on the principle that it can be defined.

Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention. Therefore, various equivalents It should be understood that water and variations may be present.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram generally showing a carbon emission display system (hereinafter, referred to as 'an expression system') 100 and a related configuration for a regional planning model according to a preferred embodiment of the present invention.

As shown in FIG. 1, the display system 100 of the present invention can identify and monitor carbon emissions (environmental emissions) for a weather model server 300 such as a weather station and individual models of a target area through a wired / wireless communication network 5 To the user client (200).

The user client 200 is a concept corresponding to a server on which the presenting system 100 of the present invention is implemented. The user client 200 is connected to the GIS information generated by the presenting system 100 of the present invention, The present invention is not limited to the name of the terminal or apparatus that can receive the rendering GIS expressed through online connection or the like.

The present invention is a system for calculating environmental emissions such as carbon and expressing the calculated environmental emissions in combination with GIS information of a corresponding zone or zone in a differential manner according to their sizes, Information about the Comprehensive Air-quality Index (CAI) can also be configured to be displayed in conjunction with the GIS.

In this case, the display system 100 according to the present invention communicates with the weather observing server 300 via the communication network 5 to display various information about the integrated atmospheric environment index And can be configured to request and receive information. Although not shown in the drawing, the presenting system 100 of the present invention can be communicably connected to an external DB server storing scenario data for a government office server or a city planning model according to need and utilization.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present disclosure system 100 will be described in detail with reference to the accompanying drawings.

2, the display system 100 of the present invention includes an interface unit 105, a scenario DB unit 110, an extraction unit 115, a GIS information storage unit 120, a GIS extraction unit 125, A level control unit 135, a level information input unit 140, a CAI receiving unit 145, a CAI region generating unit 150, and a vertex generating unit 155. [

Prior to the detailed description, each component of the present disclosure system 100 shown in FIG. 2 should be understood to be a logically distinct component rather than a physically distinct component.

That is, since each constitution corresponds to a logical constituent element for realizing the technical idea of the present invention, even if each constituent element is constituted integrally or separately, if the function performed by the logical constitution of the present invention can be realized, It is to be understood that any component that performs the same or similar function should be interpreted as falling within the scope of the present invention regardless of the consistency of the name.

The scenario DB 110 of the present invention stores one or more scenario data for a development model of a target area. The scenario data includes various information about a development model of a target area. For example, Building, land / land development, road extension, traffic volume change, information on population inflow or outflow, etc., can be recorded and data based on a predetermined format or specification.

Specifically, the scenario data is implemented in data form so as to enable subsequent data processing. The scenario data includes identification information about a target area of the development model, zone identification information for a plurality of zones that are the lowest unit units constituting the target zone, , Road identification information located between the zone and zone, and element data on changes in land, population, building or traffic volume based on the zone and the road are recorded.

More specifically, these factors data, land use type area, the road traffic-specific region (units / day), the average speed of each road link the vehicle (km / h), land use by CO ₂ emission factor (ton / m ^2), according to the model Data on air pollutant emission factors, statistics on vehicle classifications by region, statistics on fuel distribution by region, and distribution statistics on vehicle age distribution.

If the specific scenario data among the plurality of scenario data is selected from the user client 200 through the interface 105 of the present invention at S300, the extracting unit 115 of the present invention extracts the scenario data selected from the plurality of scenario data The included zone identification information, the road identification information, and the element data are extracted (S310).

The calculation unit 130 of the present invention calculates the amount of environmental emissions such as carbon emissions for zones and roads by using the extracted element data, that is, data on changes in population, building or traffic volume based on the zones and roads (S320).

Environmental emissions, such as carbon emissions, are calculated using elemental data including the various parameters mentioned above, including area (commercial area, working area, residential area, agricultural area, industrial area, etc.) (Area) -based carbon emissions can be calculated using the pollutant emission amount, land use area (m ² ), and pollutant emission coefficient per land use. The amount of carbon emitted from the road can be calculated.

Various methods known in the art such as Korean Patent Laid-Open Publication No. 2014-0022552 can be used as a method of calculating the amount of carbon (environmental discharge amount) discharged from the road or a specific region and calculating the predicted value, so a detailed description thereof will be omitted .

The GIS information storage unit 120 of the present invention stores GIS information mapped to the target area identification information, the zone identification information, and the road identification information included in the scenario data.

As described above, the scenario data includes the identification information of the zone, which is the lowest unit area constituting the target area and the target area, and each zone can be set to a plurality of zones based on the target zone, From the point of view, identification information for the road can also be generated.

As described above, the GIS information storage unit 120 of the present invention stores identification information for each zone and road, and GIS (Geographic Information System) information for each zone and road linked to the identification information, These GIS information may be provided in 2D as well as 3D GIS so that it can be displayed.

The GIS extracting unit 125 of the present invention extracts the GIS information corresponding to the zone or road identification information in which the carbon emission amount is calculated as described above among the GIS information stored in the GIS information storage unit 120 ).

When the calculation of the carbon emission amount and the corresponding GIS information extraction for each zone and road are completed, the display control unit 135 of the present invention displays the rendering GIS in which the corresponding carbon emission amount information is combined with the extracted GIS information In operation S340, the calculated carbon emission amount is displayed in a differential manner for each classification corresponding to the calculated carbon emission amount according to the reference display information divided into a plurality of categories according to the size of the carbon emission amount.

In order to further improve the visibility, it is more preferable to divide the plurality of sections according to the size of the carbon emissions and to realize a method in which the carbon emissions corresponding to the respective sections are expressed in a differential manner .

There are various methods such as a method of differentiating the level display text (A, B, C,...) And a method of expressing the dot density in the space of the corresponding area differently. The method of applying different colors to the GIS area of the road in a differential manner is most desirable for improving visibility and intuitiveness.

FIG. 5 shows a screen in which different colors are displayed in a 2D spatial region of a corresponding zone according to the size of carbon emission of the corresponding zone combined with actual 2D GIS information.

Hereinafter, another embodiment of the present invention will be described in detail to illustrate the preferred embodiments of the present invention.

Although the above-described processing of the present invention described above is based on a zone which is the lowest unit area, in order to consider various other factors integrally, the rendering GIS may be viewed from a more macro perspective, It is preferable that the GIS is integrated so that a wider area is displayed on one screen.

According to the conventional carbon emission calculation method, if the space for checking the carbon emission amount changes like this, all the parameters must be reset again and the calculation must be restarted from the beginning. Therefore, it takes considerable time and the efficiency is extremely lowered.

In order to effectively solve such a problem, the present invention proposes an embodiment for effectively solving such a problem. First, the level-level input unit 140 of the present invention inputs a level GIS, which is information about a zoom of a view displayed on the screen display means, Information is input (S430).

If the zoom level change for the displayed view is not input, a rendering GIS is expressed based on the zone unit as described above (S441). If the zoom level of the view is reduced, that is, (S433), the expression control unit 135 of the present invention integrates a plurality of zones into one expression unit area, and calculates the carbon emission amount of the expression unit area according to the following expression (1) Then, the rendering GIS is displayed (S442).

Where P is the total area of n zones, N is the number of zones to be merged, P _n is the area of the n-th zone, and Z _n is the carbon emissions of the n-th zone .

Typically, the unit of carbon emission is in tonnes, but since Table 2 is an example for efficiently explaining the preferred embodiment of the present invention, the unit such as the area including the carbon emission is omitted, and the numerical value The illustration also corresponds to an example of a virtual number for increased efficiency.

In the example of Table 2, when the zoom of the view displayed on the screen display means is reduced to ½, if the zoom of the view is reduced to ½, the width is reduced to ½ each, A wider area is expressed.

The example illustrated in Table 2 and the accompanying FIG. 6 correspond to an example in which the screen level is reduced to 1/2 so that four individual zones are displayed as one integrated area. Since carbon emissions are expressed in combination with GIS information in the area of the zone, that is, based on the area, the carbon emissions of the integrated unit of expression are calculated based on the average value of the carbon emissions per unit area before integration and the corresponding differential color And so on.

The present invention multiplies the carbon footprint of the average area per unit area by the area of the entire area of the zone to be integrated and then again divides by 4 (the number of the integrated zones) so that this association can be fully reflected, Of carbon emissions and to display the corresponding color. The above equation is applied to Equation (1).

As shown in the above equation, the carbon footprint of the new display unit area with the four zones integrated is 204.65. Examples of the reference display information described above include five steps, , The color of the newly integrated display unit area is expressed in purple when it is based on a criterion that blue is less than 150, purple less than 200, purple less than 200, purple more than 250 and less than 300 red S442). FIG. 6 illustrates an example in which four zones are integrated and displayed as one integrated display unit area.

Meanwhile, the expression control unit 135 of the present invention displays the calculated carbon emission amount by applying a differential color to the corresponding calculated classification of carbon emission amount as shown in FIG. 7, and when the road is located in the zone, The color corresponding to the carbon emission amount of the road may be preferentially displayed and the color that is gradually changed to the color corresponding to the carbon emission amount of the zone may be displayed in the zone based on the color displayed on the road.

With such a configuration, it is possible to more easily and accurately confirm information about roads located in a specific zone (region) and whether the carbon emission amount is gradually changed through visual recognition of gradual change in color.

The display system 100 according to the present invention is configured to communicate with the weather observing server 300 and receive necessary information, thereby combining the area information on the integrated air environment index with the GIS.

The Comprehensive Air-Quality Index (CAI) is a comprehensive air-quality index (CAI) that allows general users to easily understand air pollution measurements and to provide action guidelines to prevent damage from air pollution. , Which is calculated by the following formula.

In the above equation, Ip = air pollution index of the target pollutant, Cp = atmospheric concentration of the pollutant, BP _HI = pollution degree of the pollutant, maximum pollution degree, BP _LO = (Minimum interval exponent value) corresponding to I _HI = BP _HI , I _LO = exponent value corresponding to BP _LO (minimum interval exponent value), and the exponent calculated according to the formula Therefore, A, B, C, D, and E sections are marked separately.

The CAI information and the atmospheric index score of the target pollutant used to calculate it are calculated on the basis of the observation point, so that the specific region can not be generated as one unit, such as the carbon emission mentioned above.

In order to organically combine the characteristics of the CAI information with the GIS information, the CAI receiver 145 of the present invention communicates with the weather observing server 300 to acquire a plurality of observation position information on the observation point, And receives environmental index (CAI) information.

When a plurality of observation position information and integrated air atmosphere index information are received in this way, the CAI region generating unit 150 of the present invention calculates an intermediate position between the observed position information and outputs a line connecting the calculated intermediate position And generates a plurality of CAI display areas.

When the CAI display area is calculated as described above, the display controller 135 of the present invention displays the CAI information of the observation point existing in the generated CAI display area as the CAI information of the corresponding CAI display area, Color.

Since the generated CAI region is generated through the observation position information and the geometric operations of the CAI regions, a sector different from the region of the zone is formed as shown in FIG. Therefore, it is preferable to configure the CAI information to be projected in the region of the zone so that the CAI attribute information about the zone is displayed together.

To this end, the exposing controller 135 of the present invention exposes the CAI information about the corresponding zone, and when a plurality of the CAI exposed areas are set in the corresponding zone, the CAI information of the corresponding zone is calculated according to the following equation (3) And displays the CAI information in a differential color corresponding to the level of the CAI information.

R is the total area of the corresponding zone, R _n is the area occupied by the n-th CAI display area in the zone, and C _n is the area occupied by the n-th CAI display area in the corresponding zone. In this equation, B is the CAI information of the zone, N is the total number of CAI- Is the CAI information of the n-th CAI display area.

As illustrated in FIG. 8, the CAI display area is represented by a dashed line 55, and nine CAI areas are displayed in FIG. 8. When a specific zone 50 is used as a reference, a specific zone 50 and a # 1 CAI display Quot; b ", and the area overlapping with the # 8 CAI display area is "c ", the area overlapping with the CAI display area is " "to be.

In the case of the example shown in Table 3, the CAI information of the corresponding zone is calculated as follows.

The CAI index is classified into 0 to 50 A (good), 51 to 100 B (normal), 101 to 250 C (poor), and 251 to D (very bad) The expression control unit 135 of the present invention expresses the CAI information of the corresponding zone in C or in a color corresponding to C, since it corresponds to C according to the division criterion.

According to the configuration of the present invention, not only the CAI information of the corresponding zone can be calculated, but also the zone of the corresponding zone can be expressed by the differential color corresponding to the size of the CAI information.

Meanwhile, the vertex generation unit 155 of the present invention extracts a plurality of vertex information constituting the zone from the GIS information storage unit 120 (S400), and generates vertex assembly information (S410).

The GIS information is a collection of position information values based on absolute coordinates, etc., and various attribute values. Among these GIS information, the position information determining the shape of the corresponding zone is configured as vertex information, and such vertex information is extracted The display area can be linked more organically and flexibly to the environment, enlargement, and change of the displayed view.

For this, when the vertex generation unit 155 of the present invention generates vertex assembly information of the zone as described above, the expression control unit 135 of the present invention generates the vertex assembly information of the zone, Information is stored in correspondence with the vertex assembly information of the zone (S420).

That is, the independent vertex assembly information for the display area in which the carbon emission amount is expressed, which is not dependent on the GIS information, is generated so that various other application processing independent of the GIS information as well as the GIS information can be displayed.

In such a configuration, it is possible to perform the display processing of the carbon emission amount even when an error occurs in the GIS information or the GIS information linkage processing, and in addition, the rotation of the zoom magnification level of the view ), Relative rotation or enlargement processing of position coordinate information of each vertex included in the vertex assembly information corresponding to the display area information in which the carbon emission amount is expressed in color (S427) (S443) so that the area in which the color corresponding to the carbon emission amount is displayed can be synchronized.

For example, the vertex information included in the vertex assembly information corresponding to the display area information is polar coordinates (r1, θ1), (r2, θ2), (r3, θ3), (r4, (2 × r1, θ1-π / 6), (2 × r2, θ2-θ) and the vertex information of the polar coordinates are rotated ? / 6), (2 占 r3,? 3 -? / 6), (2 占 r4,? 4 -? / 6) and expresses the determined color information using an area made up of these points as a display area .

The display system 100 of the present invention displays the rendering GIS combined with the differential display method for the carbon emission amount in the GIS information (S440) as shown in FIG. 4, (S441), displaying a new GIS based on a zone or a road unit (S441), displaying a new expression unit area based on a combination of a plurality of zones (S442) or synchronizing a carbon emission display area by using a vertex information (S443) can be selectively applied to the display system, thereby realizing a display system more optimized for the user interface environment.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not to be limited to the details thereof and that various changes and modifications will be apparent to those skilled in the art. And various modifications and variations are possible within the scope of the appended claims.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory and are intended to provide further explanation of the invention as claimed. It is to be understood that various modifications may be made in the ordinary skill in the art in view of the drawings and the like.

100: An expression system according to the present invention
105: interface unit 110: scenario DB unit
115: Extractor 120: GIS information storage unit
125: GIS extracting unit 130:
134: display control unit 140: level information input unit
145: CAI receiving unit 150: CAI area generating unit
155: Vertex generation unit
200: user client 300: weather observation server

Claims (6)

Scenario data for a development model of a target area, the target zone identification information, zone identification information for a plurality of zones which are the lowest unit units constituting the target zone, road identification information A scenario DB unit storing a plurality of scenario data including element data on changes in land, population, building or traffic volume based on the zones and roads;
An extraction unit for extracting the zone identification information, the road identification information, and the element data included in the selected scenario data when specific scenario data is selected from the user client among the plurality of scenario data;
A calculation unit for calculating a carbon emission amount for the zone and the road using the extracted zone identification information, road identification information, and element data;
A GIS information storage unit storing 2D or 3D GIS information mapped to the target area identification information, the zone identification information, and the road identification information, respectively;
A GIS extracting unit for extracting each GIS information corresponding to the zone and the road identification information from which the carbon emission amount is calculated, from 2D or 3D type GIS information stored in the GIS information storage unit; And
The method of claim 1, further comprising: displaying a rendering GIS in which the carbon emission information is combined with the extracted GIS information, wherein the calculated GIS is classified into a plurality of categories And a display control unit for displaying the emission amount in a differential manner. The method according to claim 1,
Further comprising a level information input unit for receiving level information, which is information about a zoom of a view displayed on the screen display means, from the user client,
The display control unit includes:
Wherein when the input level information corresponds to reduction, a plurality of zones are integrated into one display unit area, and the carbon emission amount of the display unit area is calculated by the following equation, and then the rendering GIS is expressed: A carbon emission display system for a regional planning model.

Where P is the total area of n zones, N is the number of zones to be merged, P _n is the area of the n-th zone, and Z _n is the carbon emissions of the n-th zone . The display control apparatus according to claim 1,
The calculated carbon emission amount is expressed by applying a differential color to the calculated carbon emission amount, and when the road is located in the zone, the color corresponding to the carbon emission amount of the road is preferentially displayed, And a color is gradually displayed in the zone corresponding to the carbon emission amount of the zone based on the displayed color. The method according to claim 1,
A CAI receiving unit communicating with a weather observation server and receiving a plurality of observation location information and an associated atmospheric environment index (CAI) information about observation points; And
Further comprising a CAI region generation unit for calculating an intermediate position between the observation positional information and generating a line connecting the calculated intermediate positions to generate a plurality of CAI display regions,
The display control unit includes:
Wherein the CAI information of the observation point existing in the generated CAI display area is expressed as CAI information of the corresponding CAI display area and is displayed in a different color according to the level of the CAI information, system. The display control apparatus according to claim 4,
If a plurality of the CAI display areas are set in the corresponding zone, the CAI information of the corresponding zone is calculated according to the following equation, and CAI A carbon emission display system for a regional planning model characterized by displaying information.

R is the total area of the corresponding zone, R _n is the area occupied by the n-th CAI display area in the zone, and C _n is the area occupied by the n-th CAI display area in the corresponding zone. In this equation, B is the CAI information of the zone, N is the total number of CAI- Is the CAI information of the n-th CAI display area. The method according to claim 1,
Further comprising a vertex generation unit for extracting a plurality of vertex information constituting the zone and generating vertex assembly information which is a group of the plurality of vertex information,
The display control unit includes:
The display area information, which is a region in which a color corresponding to the carbon emission amount is displayed, is matched with the vertex assembly information of the corresponding zone by applying a differential color to each of the classes corresponding to the calculated carbon emission amount, And when the display view of the rendering GIS is rotated or enlarged, relative rotation or enlargement processing of the position coordinate information of each vertex included in the vertex assembly information corresponding to the display area information, Wherein the control unit is configured to control the shape and the area where the color corresponding to the carbon emission amount of the zone is displayed to be synchronized with each other.

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