KR101121621B1 - Drawing correction system - Google Patents

Abstract

PURPOSE: A drawing correction system of a geographical feature based on a successive aviation the photographing method is provided to offer accurate geographical information by collecting accurate aviation photo model from aviation photos. CONSTITUTION: An air absorption unit(200) adsorbs a positive film. A scanner(400) changes aviation photos into files. A control unit(800) creates aviation photo models from the positive film copy file of the scanner. A drawing image database(B1) stores a drawing image through the aviation photo model. A coordinate composition module(B2) synthesizes coordinate with the drawing image. An image editing module(B3) edits the drawing images.

Description

Drawing Correction System of Terrain based on Continuous Aerial Photography

The present invention relates to a drawing correction system of a feature based on a continuous aerial photography.

In general, a lighter is a device for producing a topographic map using a film produced from aerial photographs, and the lighteners are classified into analogue, analytic, and digital ones.

These projectors basically consist of a precision stereocoordinate measuring instrument and a coordinate reader, and can calculate a mathematical model using collinear conditional equations. External inputs required to solve the equations include the internal expression elements of the camera and the reference point. There are ground coordinates, and the internal inputs are phase coordinates measured by the projector itself.

Based on the above data, a separate working computer can calculate the model coordinates and other useful results in real time, and use the coordinate reader to display the measured data on the screen or print or plot them in hard copy form. Deliver it.

Briefly referring to the drawing method of the drawing machine, the drawing method is classified into a drawing method, an analysis drawing method, and a numerical drawing method as various drawing methods using aerial photographs.

The modified drawing method is a representative method of mechanical photogrammetry, and is a method of drawing a digital map by performing partial drawing on the area changed through aerial photographs and Dohwawon map, digitizing and merging the existing digital map.

The analysis drawing method is a method of performing an operation by checking an existing numerical map directly on a screen connected to a computer, and it is easy to check a correction factor through comparison with an aerial photograph, and directly to modify a drawing file for updated contents. In the case of updating the digital map by analysis photogrammetry, it is possible to convert large numbers of aerial photographs into the ground coordinate system at the same time for drawing large areas.

The numerical drawing method is a drawing operation using an analytical drawing method and a moon image file. When updating a digital map by the numerical drawing method, an aerial photographing process is required, and the first aerial photograph is taken by a digital camera. Or by scanning the aerial quantization film through a high resolution scanner.

When the drawing operation is performed in the above manner, fast and accurate drawing data can be obtained.

On the other hand, features on the ground are constantly changing. Therefore, it is necessary to correct the geographic information collected through the scanning operation from time to time.

At this time, the fuser extracting the aerial photograph model may be precisely operated without being influenced by external environmental factors (such as sudden darkening of the surroundings).

Therefore, there is a need for a system that can stably collect the aerial photograph model and correct existing geographic information.

The present invention is to solve the above problems, it is possible to accurately correct the existing geographic information even in a dark environment, the error does not occur in the fuser, through this can collect the exact aerial photo model from the aerial photo film The problem to be solved is to provide a drawing correction system for a feature based on continuous aerial photography.

The present invention for solving the above problems,

It is provided in the inner center and the scanner mounting portion 111 is formed in the discharge hole (111a) is opened to the bottom, the front is provided in front of the scanner mounting portion 111 and the first glass plate mounting plate (112a) protrudes in the upper inner It is provided at the rear of the unit 112 and the scanner mounting unit 111 to form the scanner receiving groove (h) together with the scanner mounting unit 111 and the front portion 112, and The second glass plate mounting plate 113a facing the first glass plate mounting plate 112a protrudes from the rear portion 113 and the front portion 112, one end of which is opened to the upper portion of the front portion 112 and the other end thereof. A cooling passage 114 opening to the scanner accommodation groove h to allow external air to flow into the scanner accommodation groove h, and a main line 115a and a rear portion formed in the rear portion 113 and opened laterally ( Branch line 115b formed in the rear portion 113 and formed in the longitudinal direction of the rear portion 113 in communication with the main line 115a, formed in the rear portion and upwards on the top A positive film fixing hole (115c1) formed in the opening and the positive film fixing portion 115 having a suction line (115c) is formed in communication with the branch line (115b) and provided with a plurality corresponding to the size of the positive film (F); A scanner accommodating part 110 provided at an upper end of the rear part 113 and having a seating part 116 to form an upper end of the rear part 113 and a chin so that the end of the positive film F is seated; An air suction device accommodating part 120 formed adjacent to the scanner accommodating part 110; Both ends are installed in the first and second glass plate mounting plates (112a, 113a), respectively, the upper surface is a drawing with a transparent glass plate 130 located on the same line as the positive film adsorption hole (115c1) of the suction line (115c) With primitive 100:

It is provided with a connection portion 210 which penetrates through the air suction device accommodation part 120 and is connected to the main line 115a of the positive film fixing part 115, and is installed in the air suction device accommodation part 120, and the suction line 115c is provided. Air suction device 200 for adsorbing the positive film (F) seated in the positive film adsorption hole (115c1) of):

The cover part 300 is rotatably installed on the drawing base body 100 to open and close the upper portion of the scanner accommodating part 110:

It is accommodated in the scanner receiving groove (h) of the scanner receiving unit 110, is installed in the lower portion of the glass plate 130, and converts the aerial photo into a file by reading as if copying an aerial photo quantum film (F) seated on the glass plate 130 And the scanner 400 to store:

A plurality of support members 500 and spaced apart from each other are respectively installed in the lower edge of the drawing base body 100:

A plurality of insertion holes 611 are formed at a lower portion thereof in a length direction, and a detector main body 610 having both ends installed at a lower portion of each support member; It is inserted into the insertion hole 611 of the detector body 610 and is provided in the lower portion of the insertion portion 621 and the insertion portion 621 is connected to the plurality of insertion portions 621 and in close contact with the floor A sponge member 620 having a close contact portion 622 for absorbing water and a sensor member 610 which are insulated along the length direction, and are disposed above the sponge member inserting portion 621 so that a fine current flows. With a portion 630, a plurality of moisture sensing unit 600 is installed between each support member 500 and:

Is installed in the lower portion of the main body 100, suction the outside air through the cooling passage 114 of the scanner receiving portion 110, to cool the inside of the scanner receiving portion 110, and to cool the sponge member 620 Drying pan apparatus 700 and:

The air suction device 200, the scanner 400, and the fan device 700 are operated and controlled, and when the current of the moisture detecting unit conductor 630 changes by more than a reference value, it detects this and turns off all power, while the scanner ( The control unit 800 for generating an aerial photograph model from the positive film copy file of 400 and outputting the aerial photograph model to the drawing image processing apparatus B and:

An input unit 900 installed at the drawing base 100 and inputting an operation signal to the control unit 800:

The display apparatus 1000 installed in the drawing base body 100 and operated and controlled by the control unit 800:

A fire detection sensor (FS) installed in the drawing main body 100 and operated and controlled by the control unit 800 and detecting a fire occurrence;

Equipped with an injection nozzle (EI1) facing the fuser (A), it is installed on the upper portion of the air intake device receiving unit 120, the operation is controlled by the control unit 800, the control unit 800 is a fire detection sensor Receiving a fire signal from the (FS), the extinguishing powder injection device (EI) for injecting the extinguishing powder through the injection nozzle (EI1),

Support lamp LA1 is installed on the fire extinguishing powder injection device (EI), and a lamp (LA2) installed on the upper part of the support (LA1) toward the fuser (A) and operated and controlled by the control unit (800). Equipped lighting equipment (LA),

A lighter (A) having a,

Drawing image DB (B1) for generating and storing drawing images through an aerial photograph model from the drawing machine (A): Coordinate synthesis module (B2) for combining coordinates with drawing images: Image for connecting and editing a plurality of drawing images Drawing image processing apparatus (B) having an editing module (B3),

Characterized in that it comprises a.

According to the present invention as described above, even in a dark environment, it is possible to accurately correct the existing geographic information, there is no error in the fuser, through which the accurate aerial information correction by collecting the accurate aerial photograph model from the aerial photo film There is a possible effect.

1 is a system diagram showing an overall system of the present invention,
2 is a perspective view showing a part of the fuser according to the present invention;
3 is a partial front cross-sectional view of the present invention,
4 is a view showing a portion Y of the present invention,
5 is a view showing a portion Z of the present invention,
6 is a plan view of the line XX excluding the cover unit and the lighting device;
7 and 8 are views showing the operation of the present invention,
9 is a front sectional view showing another embodiment of the present invention.

1 to 6 are views showing the present invention, the present invention will be described with reference to FIGS. 1 to 6 as follows.

The drawing system according to the present invention includes a drawing device (A) and a drawing image processing device (B) for receiving an aerial photograph model from the drawing device (A).

The fuser A opens and closes the drawing main body 100 on which the quantizing film F is disposed, the air suction device 200 provided on the drawing main body 100, and the drawing main body 100. The cover unit 300, the scanner 400 installed in the drawing base body 100, a plurality of supporting members 500 installed at the lower edge of the drawing base body 100, and each supporting member 500. ) Between the moisture detection unit 600), the fan device 700 which is installed in the lower portion of the main drawing body 100 to generate hot air, and the control unit 800 installed in the main drawing body 100 and , An input unit 900 for inputting a signal, a display device 1000 indicating an operation state of each component, a fire detection sensor FS and an fire extinguishing powder injection device EI controlled by the control unit 800. ), Equipped with a lighting device (LA).

The drawing base body 100 includes a scanner accommodating part 110 in which the scanner 400 is accommodated, an air suction device accommodating part 120 provided adjacent to the scanner accommodating part 110, and a scanner accommodating part 110. Equipped with a glass plate 130 is built in.

The scanner accommodating part 110 is provided at the scanner mounting part 111 provided at the inner center, at the front part 112 provided at the front of the scanner mounting part 111, and at the rear of the scanner mounting part 111. The rear portion 113, the cooling passage 114 formed in the front portion 112, the positive film fixing portion 115 formed in the rear portion 113, and the upper portion of the positive film fixing portion 115 It has a seating portion 116 is provided.

The scanner installation unit 111 is provided in the inner center, and the discharge hole 111a opened downward in the center.

The front portion 112 is provided in front of the scanner mounting portion 111 and the first glass plate mounting plate 112a protrudes from the upper side thereof.

The rear portion 113 is installed at the rear of the scanner mounting portion 111, and forms the scanner accommodation groove (h) together with the scanner mounting portion 111 and the front portion 112, and the front portion (on the upper side) A second glass plate mounting plate 113a facing the first glass plate mounting plate 112a of 112 protrudes.

The cooling passage 114 is provided in the front portion 112, one end is opened to the upper portion of the front portion 112 and the other end is opened to the scanner accommodation groove (h), the outside air is the scanner accommodation groove (h) To get into the In this case, a plurality of cooling furnaces 114 may be provided.

The positive film fixing part 115 is formed in the rear portion 113, the main line 115a opened laterally, and formed in the rear portion 113 and in communication with the main line 115a, the rear portion 113 The branch line 115b formed along the longitudinal direction of the positive and negative film film adsorption holes 115c1 formed in the rear portion and opened upward at the top thereof is formed in communication with the branch line 115b, but the size of the positive film F It has a suction line (115c) is provided with a plurality corresponding to.

The seating portion 116 is provided at the upper end of the rear portion 113 and forms the upper end of the rear portion 113 so that the end of the positive film (F) is seated.

The air suction device accommodating part 120 has a space formed therein, and the air suction device 200 is accommodated therein.

The glass plate 130 is made of a transparent material, and both ends of the glass plate 130 are provided in the first and second glass plate mounting plates 112a and 113a, respectively, and are disposed in the scanner accommodation groove h. At this time, the upper surface of the glass plate 130 is located on the same line as the positive film adsorption hole (115c1) of the suction line (115c).

The air suction device 200 has a connection portion 210 connected to the main line 115a of the positive film fixing part 115 through the air suction device accommodation part 120, and the air suction device accommodation part 120. ) To adsorb the positive film (F) seated in the positive film adsorption hole (115c1) of the suction line (115c). At this time, the connection portion 210 preferably forms a hose shape.

In the present embodiment, the air suction device 200 may suck air and fix an end portion of the positive film F seated on the positive film suction hole 115c1 of the suction line 115c. Anyway.

One side of the cover part 300 is rotatably installed at the rear portion of the drawing base body 100 to open and close the upper portion of the scanner accommodating part 110. In this case, the cover part 300 pressurizes the positive film F seated on the glass plate 130.

The scanner 400 is accommodated in the scanner accommodating groove h of the scanner accommodating part 110 and installed at a lower portion of the glass plate 130, and copies the aerial photographic film F seated on the glass plate 130. Read and convert the aerial photograph into a file and save it. On the other hand, the scanner 400 is generally used for a fuser, and a detailed description thereof will be omitted.

The support member 500 forms a hexahedron shape and is installed at a lower edge portion of the drawing base body 100 to space the drawing base body 100 from the bottom surface. At this time, four support members 500 are provided, and are respectively installed at corner portions of the drawing base body 100 and spaced apart from each other.

The moisture detecting unit 600 includes a detector main body 610 installed between each support member 500, a sponge member 620 installed at the sensor main body 610 to absorb moisture, and a detector main body. The conductor part 630 built in 610 is provided, and is installed between each support member 500.

The detector body 610, a plurality of insertion holes 611 are formed in the lower portion in the longitudinal direction, both ends are provided under each support member 500. In this case, a space 612 communicating with the insertion hole 611 is formed in the longitudinal direction of the detector body 610.

The sponge member 620 is inserted into the insertion hole 611 of the detector main body 610 and the insertion portion 621 to absorb the water to prevent the water from moving to the lower portion of the main body 100, the insertion portion The lower portion 621 is provided to connect the plurality of inserting portions 621 and has a close contact portion 622 to be in close contact with the bottom to absorb water. In this case, the sponge member 620 may be variously modified as long as it can absorb water.

The conductor part 630 is insulated along the lengthwise direction of the space part 612 of the detector body 610 and is disposed above the sponge member inserting part 621 so that a minute current flows. In this case, when the water is absorbed into the sponge member 620, the conductor part 630 generates a current change, and through this, it is sensed that water exists in the main body 100.

The fan device 700 is installed under the drawing base 100, is disposed below the discharge hole 111a, and sucks outside air through the cooling passage 114 of the scanner accommodating part 110. The inside of the scanner accommodating part 110 is cooled and the sponge member 620 is cooled.

The control unit 800, the operation operation control the air suction device 200, the scanner 400, and the fan device 700, and detects when the current of the moisture detection unit conductor 630 changes by more than the reference, all Turn off the power. In addition, the control unit 800 generates an aerial photograph model from the positive film copy file of the scanner 400 and outputs the aerial photograph model to the drawing image processing apparatus (B). In this case, the control unit 800 may output the aerial photograph model to the drawing image processing apparatus B through a separate network.

The input unit 900 is installed in the drawing base body 100 and inputs an operation signal to the control unit 800.

The display apparatus 1000 is installed in the drawing base body 100, and is operated by the control unit 800 to indicate the operation state of each component.

The fire detection sensor (FS) is installed in the main body 100, detects smoke or heat, the fire occurs in the fuser (A), and outputs a fire signal to the control unit (800). At this time, the control unit 800 drives the fire extinguishing powder injection device (EI) so that the fire extinguishing powder injection device (EI) injects the fire extinguishing powder.

The fire extinguishing powder spraying device EI is equipped with the fire extinguishing powder spray nozzle EI1 facing the fuser A, and is installed above the air suction device accommodating part 120. At this time, the fire extinguishing powder injection device EI is provided with an on / off valve, and when the control unit 800 receives a fire signal from the fire detection sensor FS, the fire extinguishing powder injection device EI is opened. Digestive powder is sprayed. At this time, the extinguishing powder is a conventional one used for a fire extinguisher.

The lighting device LA is installed at the upper center of the fire extinguishing powder injection device EI and installed upward, and is installed at the upper part of the support LA1 to face the fuser A, and to the control unit. Operationally controlled by 800, it is equipped with a light (LA2) that is turned on or off. At this time, the lamp (LA) brightens the periphery of the fuser (A) when turned on.

The drawing image processing device (B) includes a drawing image DB (B1) for generating and storing a drawing image through an aerial photograph model from the drawing unit (A), and a coordinate combining module (B2) for combining coordinates with the drawing image. And an image editing module B3 for connecting and editing a plurality of drawing images.

The drawing image DB B1 generates a drawing image including data of contours, features, and the like through an aerial photograph model, and stores the drawing image.

The coordinate synthesizing module B2 synthesizes coordinates in the drawing image, and typically combines the coordinates based on a reference point displayed on the drawing image. The reference point is displayed in the process of creating a drawing image, and the display method may include a natural display method through photography or an artificial display method through drawing.

The image editing module B3 connects and edits the plurality of drawing images. When the GIS system links various pieces of information to a corresponding point of the drawing image, the image editing module B3 may perform work efficiently.

Hereinafter will be described the operation of the present invention.

First, the operator sets each component to operate through the input unit 900.

In order to accurately scan the positive film F, when the cover 300 is closed, the positive film F seated on the glass plate 130 should not flow in the scan position.

On the other hand, in the case of the present invention, when the worker seats the positive film (F) on the glass plate 130, the end of the positive film (F) is on the upper side of the positive film suction hole (115c1) of the positive film fixing part suction line (115c) Is placed.

At this time, since the air suction device 200 sucks air at a constant pressure through the positive film adsorption hole 115c1 of the positive film fixing part suction line 115c, the end of the positive film F is fixed.

Then, if the worker closes the cover 300 for scanning, the positive film (F) is not flow by the external force while the cover 300 is closed. Therefore, the positive film F made by aerial photography can be precisely scanned.

When the positive film F is fixed by the cover part 300 as described above, the operator inputs a signal to the input unit 900 to drive the scanner 400. In this case, the worker may stop the driving of the air suction device 200.

Then the positive film (F) is scanned, the control unit 800 generates an aerial photograph model. At this time, the control unit 800 sends the aerial image model to the drawing image processing apparatus (B).

In this case, the worker generates and stores a drawing image in which data such as terrain information is input through the drawing image DB B1 of the drawing image processing apparatus B, inputs coordinates to the generated and stored drawing images, Link and edit drawing images.

On the other hand, the fuser (A) is an expensive electronic product, very vulnerable to moisture, when a failure occurs, a lot of repair costs are consumed, and when the error occurs in the fuser (A), it is difficult to precisely scan.

However, in the case of the present invention, when water flows around the fuser (A) by a mistake of an operator or someone else, it is possible to prevent the water from entering the fuser (A).

That is, when the water penetrates the bottom of the fuser A, the sponge member 620 of the moisture sensing unit 600 absorbs water.

At this time, the current flowing through the conductor portion 630 of the moisture sensing unit 600, the change occurs by the moisture of the sponge member 620, the control unit 800 turns off all power.

Therefore, various configurations of the present invention can be safely protected.

In addition, the present invention can cool the drawing main body 100 by the fan device 700 that is operated normally, it is possible to drive the fuser (A) more stably.

In addition, the present invention, when the fire occurs in the fuser (A), it is possible to extinguish the fire initially.

That is, the present invention, when a fire occurs in the fuser (A), the fire detection sensor (FS) detects this, outputs a fire signal to the control unit 800, the control unit 800 receiving the fire extinguishing powder By driving the injection device (EI), the fire extinguishing powder injection device (EI) as shown in Figure 7 to inject the fire extinguishing powder.

Further, the present invention can stably perform the drawing work even when the lighting of the drawing work room is suddenly turned out or the drawing work is performed in a place where there is no lighting facility.

That is, in the present invention, when the surroundings are dark, the operator can smoothly perform the drawing work in a dark environment by driving the lighting device LA as shown in FIG. 8.

Figure 9 shows another embodiment of the present invention, the sponge member 620 of the moisture detection unit 600 of the present invention may be provided with a shock absorbing portion 623 in the corner.

The shock absorbing part 623 is disposed below each of the supporting members 500, and normally cancels the vibration generated in the fuser A, so that the fuser A can stably scan. When there is water around the fuser (A), it absorbs the water, so that the water does not seep into the fuser (A).

On the other hand, in the above embodiment, when the moisture sensing unit 600 having the shock absorbing unit 623 is installed at one side of the support member 500, the moisture sensing unit 600 does not have the shock absorbing unit 623 at the other side of the support member 500. ) Is installed.

A; Lighter 100; Drawing
200; Air suction device 300; Cover
400; Scanner 500; Supporting member
600; Moisture detection unit 700; Hot air fan system
800; Control unit 900; Input unit
1000; Display device FS; Fire sensor
EI; Fire extinguishing powder LA; Lighting equipment
B; Drawing Image Processing Equipment

Claims (1)

It is provided in the inner center and the scanner mounting portion 111 is formed in the discharge hole (111a) is opened to the bottom, the front is provided in front of the scanner mounting portion 111 and the first glass plate mounting plate (112a) protrudes in the upper inner It is provided at the rear of the unit 112 and the scanner mounting unit 111 to form the scanner receiving groove (h) together with the scanner mounting unit 111 and the front portion 112, and The second glass plate mounting plate 113a facing the first glass plate mounting plate 112a protrudes from the rear portion 113 and the front portion 112, one end of which is opened to the upper portion of the front portion 112 and the other end thereof. A cooling passage 114 opening to the scanner accommodation groove h to allow external air to flow into the scanner accommodation groove h, and a main line 115a and a rear portion formed in the rear portion 113 and opened laterally ( Branch line 115b formed in the rear portion 113 and formed in the longitudinal direction of the rear portion 113 in communication with the main line 115a, formed in the rear portion and upwards on the top A positive film fixing hole (115c1) formed in the opening and the positive film fixing portion 115 having a suction line (115c) is formed in communication with the branch line (115b) and provided with a plurality corresponding to the size of the positive film (F); A scanner accommodating part 110 provided at an upper end of the rear part 113 and having a seating part 116 to form an upper end of the rear part 113 and a chin so that the end of the positive film F is seated; An air suction device accommodating part 120 formed adjacent to the scanner accommodating part 110; Both ends are installed in the first and second glass plate mounting plates (112a, 113a), respectively, the upper surface is a drawing with a transparent glass plate 130 located on the same line as the positive film adsorption hole (115c1) of the suction line (115c) With primitive 100:
It is provided with a connection portion 210 which penetrates through the air suction device accommodation part 120 and is connected to the main line 115a of the positive film fixing part 115, and is installed in the air suction device accommodation part 120, and the suction line 115c is provided. Air suction device 200 for adsorbing the positive film (F) seated in the positive film adsorption hole (115c1) of):
The cover part 300 is rotatably installed on the drawing base body 100 to open and close the upper portion of the scanner accommodating part 110:
It is accommodated in the scanner receiving groove (h) of the scanner receiving unit 110, is installed in the lower portion of the glass plate 130, and converts the aerial photo into a file by reading as if copying an aerial photo quantum film (F) seated on the glass plate 130 And the scanner 400 to store:
A plurality of support members 500 and spaced apart from each other are respectively installed in the lower edge of the drawing base body 100:
A plurality of insertion holes 611 are formed at a lower portion thereof in a length direction, and a detector main body 610 having both ends installed at a lower portion of each support member; It is inserted into the insertion hole 611 of the detector body 610 and is provided in the lower portion of the insertion portion 621 and the insertion portion 621 is connected to the plurality of insertion portions 621 and in close contact with the floor A sponge member 620 having a close contact portion 622 for absorbing water and a sensor member 610 which are insulated along the length direction, and are disposed above the sponge member inserting portion 621 so that a fine current flows. With a portion 630, a plurality of moisture sensing unit 600 is installed between each support member 500 and:
Is installed in the lower portion of the main body 100, suction the outside air through the cooling passage 114 of the scanner receiving portion 110, to cool the inside of the scanner receiving portion 110, and to cool the sponge member 620 With fan apparatus 700 for drying and:
The air suction device 200, the scanner 400, and the fan device 700 are operated and controlled, and when the current of the moisture detecting unit conductor 630 changes by more than a reference value, it detects this and turns off all power, while the scanner ( The control unit 800 for generating an aerial photograph model from the positive film copy file of 400 and outputting the aerial photograph model to the drawing image processing apparatus B and:
An input unit 900 installed at the drawing base 100 and inputting an operation signal to the control unit 800:
The display apparatus 1000 installed in the drawing base body 100 and operated and controlled by the control unit 800:
A fire detection sensor (FS) installed in the drawing main body 100 and operated and controlled by the control unit 800 and detecting a fire occurrence;
Equipped with an injection nozzle (EI1) facing the fuser (A), it is installed on the upper portion of the air intake device receiving unit 120, the operation is controlled by the control unit 800, the control unit 800 is a fire detection sensor Receiving a fire signal from the (FS), the fire extinguishing powder injection device (EI) for injecting the extinguishing powder through the injection nozzle (EI1),
Support lamp LA1 is installed on the fire extinguishing powder injection device (EI), and a lamp (LA2) installed on the upper part of the support (LA1) toward the fuser (A) and operated and controlled by the control unit (800). Equipped lighting equipment (LA),
A lighter (A) having a,
Drawing image DB (B1) for generating and storing drawing images through an aerial photograph model from the drawing machine (A): Coordinate synthesis module (B2) for combining coordinates with drawing images: Image for connecting and editing a plurality of drawing images Drawing image processing apparatus (B) having an editing module (B3),
Drawing correction system of the feature based on the continuous aerial shooting method comprising a.

Images