KR101318324B1 - System for generating a walking route poi based on image - Google Patents

Abstract

PURPOSE: An image-based walk route POI display system can manage various POI information displayed on a user terminal not to be overlapped or repeated. CONSTITUTION: An area information generator (140) generates area information of display POI in which 3D display POI is projected in 2D. The area information generator uses characteristic information and status information of the display POI and generates the area information of the display POI projected onto a display area of a terminal. An information processor (150) generates location information in which text information of the display POI is outputted with a coordinate within the generated area information of the display POI. The information processor transmits the text information of the display POI along with the generated location information to the terminal. [Reference numerals] (100) POI display system; (110) Reception unit; (120) Storage unit; (130) POI extraction unit; (140) Area information generator; (150) Information processor; (160) Section division unit; (170) Path information unit

Description

System for generating a walking route POI based on image}

The present invention relates to a system for displaying POI information and the like associated with a walking path together with an image output from a user terminal. More specifically, the present invention classifies each POI region of an image output from a user terminal and outputs a POI text output position. The present invention relates to a walking path POI presentation system that dramatically improves user perception by preventing overlapping of POI text information by linking with location information in each of the divided POI areas.

Recently, an augmented reality technique, that is, a technique of combining virtual world information including additional information such as text, location information, category category, and the like into real world information, is provided to a user as a single image.

Such augmented reality technique is a result of rapid development of a mobile terminal such as a smart phone, and provides a variety of information provided by an item provider to actual world information that a user confirms through a camera provided in the mobile terminal, It is configured to realize various user convenience functions such as terrain recognition, destination confirmation, and information on surrounding buildings.

As an augmented reality technique, a service that allows a user to more easily and easily identify a destination to be visited is recently introduced by merely providing information about the surrounding terrain and further fusing information on the user's walking path have.

This augmented reality technique generally provides the user with the location information of the surrounding terrain and the related information of the terrain using the GPS information and the real world information transmitted from the user terminal to the service providing entity, A method of checking what kind of terrain is present around the terminal is applied.

However, in such a case, since the terrain related information provided to the user terminal can not be related to each other and simply a plurality of information is provided to the user terminal in a broad casting manner, When the user confirms the related information of the surrounding terrain through the means, it is essential that the related information on the surrounding terrain (the name of the building is a representative example) overlaps and overlaps with each other so that the user's perception of the surrounding terrain information is remarkably low I have a problem.

In addition, since the information provided by the service provider is merely information transmitted to the user terminal unilaterally in the service utilizing the augmented reality technique, the location of the user terminal, that is, the location where the user is present, In addition, there is a lack of practical and diverse information available through interactivity, which should be overcome.

SUMMARY OF THE INVENTION The present invention has been developed in order to solve the above-mentioned problems in a more effective manner, and it is an object of the present invention to provide a navigation system and a navigation system, The present invention provides a system capable of dramatically maximizing the perceptibility, visibility, and the like.

In addition, the present invention is not limited to providing only information on the surrounding terrain using the current position of the user and the destination or route information that the user desires to reach, and may further include user direction information, So that it is possible to more easily and quickly identify the POI around the walking path and the walking path of the user.

Other objects and advantages of the present invention will be described below, and will be understood by 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.

The image-based walking path POI display system of the present invention for achieving the above object comprises: a receiving unit for receiving state information including current setting information of a camera module mounted on a terminal and location information of the terminal from the terminal; A storage unit for storing characteristic information on the position, shape, and size of the POI and a three-dimensional map database for the POI; A POI extraction unit for extracting an expression POI that is a POI corresponding to the state information received from the terminal and extracting a three-dimensional expression POI corresponding to the expression POI in the three-dimensional map database; Generating area information of the presentation POI in which the three-dimensional presentation POI is projected in two dimensions, and projecting onto the screen display means of the terminal by using characteristic information of the presentation POI and current setting information of the camera module An area information generation unit generating area information of the POI; And an information processing unit for generating location information for outputting text information of the display POI to coordinate values in the area information of each generated display POI and transmitting the text information of the display POI to the terminal together with the generated position information, .

When the area information of each exposed POI extracted by the area information generating unit is overlapped, the area overlapped with the exposed POI located close to the terminal is allocated using the characteristic information, The information processing unit may be configured to generate the position information by using the coordinate values in the area information of each exposed POI generated in the area dividing unit.

In addition, the present invention may further include a route information unit for generating and storing route information obtained by sorting the POIs existing from the source to the destination when the source and destination information are transmitted from the terminal, And generating the text information of the path POI so as to be distinguished from the text information of the other display POIs if the display POI is a path POI that is a POI existing on the path information.

More preferably, the information processing unit may display more path POIs than the path POIs currently displayed on the screen display means of the terminal based on the current setting information transmitted from the terminal and the location information of the terminal. The viewing angle guide information of the terminal may be further transmitted to the terminal.

Here, the state information of the present invention may include angle of view information of the camera module, zoom state information, and resolution information of the terminal. In this case, the area information generation unit may determine coordinates of edge points of the expressed POI below. The area information of the expressed POI may be generated by calculating the area of the edge point coordinates calculated by the following equation.

In the above equation, Px and Py are the x and y coordinates of the edge point of the three-dimensional display POI projected onto the two-dimensional screen display means, Z is the zoom factor, MP is the number of pixels on the diagonal line of the screen display means, The x coordinate, the z coordinate, and the y coordinate of the 3D point of view POI edge point with the camera module as a reference point, and the angle of view information of the camera module.

Also, the status information of the present invention may include at least one of horizontal rotation angle, vertical rotation angle information, and direction rotation angle information of the camera module generated using a sensor built in the terminal, The information generation unit is configured to generate the respective edge point coordinate values by reflecting the position change values corresponding to the horizontal rotation angle, the vertical rotation angle, or the direction rotation angle to the respective edge point coordinate values calculated by Equations 1 and 2 .

In order to realize a more preferred embodiment, the area information generator of the present invention may be configured to generate area information on only an exposed POI located within a reference distance based on the terminal, When the region of the POI is out of the terminal image region defined by the screen display means of the terminal, the display region information of the displayed POI is generated by clipping the displayed POI region into the region corresponding to the terminal image region .

The image-based walking path POI display system according to the present invention goes beyond the dimension of checking the information on the surrounding features together with real-world image information that the user checks through a camera mounted on his terminal in relation to the augmented reality service. Each information about the surrounding features can be configured to be output without being overlapped with each other by being linked with the individual areas where the surrounding features are displayed. A more user-oriented interface can realize improved recognition and visibility of the surrounding features. We can realize environment.

In addition, the present invention can configure a POI (landform) existing on a route to a destination from a user to be different from other landforms, thereby making it easier and easier to guide the destination identification and arrival process, Can be realized.

Furthermore, the present invention provides guidance information on the user's gaze angle so as to more effectively check the POI existing on the route to the destination more positively than the provision of only the surrounding POI information, It is possible to induce the POI to be easily identified by the user, thereby maximizing the user's convenience.

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.
1 is a schematic view showing an overall configuration of a POI display system according to a preferred embodiment of the present invention;
FIG. 2 is a block diagram showing a configuration of a POI display system according to a preferred embodiment of the present invention. FIG.
FIG. 3 is a flowchart illustrating a process of POI display processing according to a preferred embodiment of the present invention.
4 is a view showing a view proportional relationship between a video image and a real-world image on the basis of a camera,
5 is a view for explaining setting of image coordinates based on a user terminal,
6 is a view for explaining a method of determining an edge point constituting a POI area based on a correlation between a 3D terrain DB and a user terminal,
FIG. 7 is a diagram illustrating a proportional correlation between a user terminal, an image region, and a real world region, and coordinates of a POI edge point based on the proportional correlation;
8 is a view for explaining a preferred embodiment of the POI area information of the present invention,
Figure 9 illustrates a preferred embodiment of a plurality of POI regions generated with edge points of the present invention;
10 is a diagram illustrating a method of dividing or allocating overlapping POI regions according to a preferred embodiment of the present invention.
11 is a view showing each POI area displayed together with image information according to a preferred embodiment of the present invention.
12 illustrates a preferred embodiment of POI related information transmitted from the system of the present invention to a user terminal;
13 is a view for explaining the direction of rotation of a user terminal and its reference axis,
14 is a diagram for explaining a relationship between a real world coordinate system and a coordinate system reflecting a rotation angle of the camera module,
15 is a diagram for explaining a relationship between a virtual image area and a real world area.

Hereinafter, exemplary 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 interpreted 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 this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

1 is a schematic diagram showing an overall configuration related to a video information-based POI presentation system 100 (hereinafter referred to as a presentation system) according to an embodiment of the present invention.

The display system 100 of the present invention can be implemented not only in the user terminal itself, but also in a way that the user terminal is connected to the server operating the display system through the wired / wireless communication network 20 and linked to the server . Generally, the amount of 3D map data required for generating and providing POI related information is vast and requires a considerable amount of time for computation processing. Therefore, a high-specification hardware resource is required to realize objectivity such as real-time processing.

Therefore, the basic processing data or interfacing may be provided to the smartphone 10, the notebook computer 12, etc. rather than the method of providing the POI information by processing in the terminal after all the related programs are loaded on the user terminal 10. [ And an operation of generating POI display position based on GPS position information and state information input from the user terminal 10 and storing and managing the entire network data for this purpose are implemented in the server The present invention is not limited thereto.

(GPS information), various status information on the camera module, or the like, or the like, by the driving of the predetermined program installed in the user terminal 10-1, 10-2, 10- Destination information on the walking path desired by the user is input to the presenting system 100 of the present invention through the wired / wireless communication network 20, the presenting system 100 of the present invention is capable of displaying, on the basis of the received information, And outputs information to the user terminal 10 via the wireless communication network 20. The user terminal 10 may be connected to the user terminal 10 via the wireless communication network 20, for example.

According to an embodiment of the present invention, the display system server 100 of the present invention is connected to an institution server 50 such as a predetermined government office or the like that manages map data or traffic characteristics, Or update of network data, and the like.

Hereinafter, an embodiment in which the presentation system 100 of the present invention is implemented as a server corresponding to a client will be described below, but the presentation system 100 of the present invention is not limited to this and can be implemented through a single terminal Of course it is possible.

FIG. 2 is a block diagram illustrating the configuration of the display system 100 according to an exemplary embodiment of the present invention. FIG. 3 is a flowchart illustrating a POI display processing according to an exemplary embodiment of the present invention.

2, the display system 100 of the present invention includes a receiving unit 110, a storage unit 120, a POI extracting unit 130, an area information generating unit 140, an information processing unit 150, An install unit 160 and a route information unit 170. [

Hereinafter, the POI referred to in connection with the preferred embodiment of the present invention is an abbreviation of Point Of Interest, which refers to a feature located on a map in a technical field related to geographical information. The POI is a milestone or route identification As a feature for recognition, buildings, intersections, crosswalks, and overpasses can be targets.

First, in the storage unit 120 of the present invention, characteristic information on the position, shape, and size of the POI and a three-dimensional map database of the POI are stored. This database is a database on national basic maps, road name address data, and other maps that can be provided from a national agency server or a private server, and since a 3D system for all the terrain features is already implemented, It goes without saying that the necessary information and data relating to the implementation of the invention may additionally be included in this 3D system database.

The receiving unit 110 of the present invention receives the current setting information of the camera module mounted on the user terminal 10 and state information including the location information of the terminal from the terminal and stores the received state information (S110, S120).

The state information may include GPS position information generated from a GPS module embedded in the terminal, angle of view information of the camera module, zoom state information, and resolution information of the terminal. The camera module according to the specification of the user terminal 10 may be included. After the DB for the angle of view, focus, resolution, etc. is pre-established, and receiving information on the terminal specification, the DB may be operated by reading state information corresponding to the transmitted information from the DB.

As described later, in the state information, one of the horizontal rotation angle, the vertical rotation angle information, and the direction rotation angle information of the camera module generated using the sensor built in the terminal 10 for providing more precise and accurate POI information The above information may be included. As will be described later, the rotation angle information is utilized as basic data for grasping an accurate gaze view (view) in which the user views the terrain at the current position through the camera module built in the terminal 10. [

It goes without saying that the transmission of the status information to the receiver 100 may be performed by the execution of a driving application (S100) associated with providing POI information at the terminal of the user terminal 10.

When the state information is transmitted from the terminal 10 as described above, the POI extracting unit 130 of the present invention extracts POIs corresponding to the state information received from the terminal 10 in the three-dimensional map database stored in the storage unit 120, Extracting POI. As described above, since 3D data for all the terrain exist, if the position information of the current terminal and the view information of the camera are secured, analysis processing with the 3D data is performed to present You can see what the POI is. When the display POI is confirmed, information on the name, type, building name, street name address, and the like of the displayed POI is extracted.

The POI extracting unit 130 of the present invention extracts the 3-dimensional display POI corresponding to the displayed POI along with the extraction of the displayed POI (S130) and transmits the extracted information to the area information generating unit 140 of the present invention .

When the 3-dimensional display POI information is transmitted to the area information generation unit 130 of the present invention, the area information generation unit 130 generates area information of the display POI to which the 3-dimensional display POI is projected in two dimensions, And generates the area information of the displayed POI to be projected onto the screen display means of the terminal (10) using the characteristic information of the displayed POI stored in the storage unit (120) and the current setting information of the camera module.

The processing for this will be described in more detail with reference to FIGS. 4 to 7 attached hereto. 4, k represents the center of the camera module (terminal), and R represents the image of the real world. do. I corresponds to an image displayed on the screen display means (LCD) of the terminal as a virtual image region corresponding to the image of the real world.

An image is displayed on the screen display means of the terminal at a position corresponding to the virtual image area shown in Fig. That is, the real-world area ABCD is projected onto the image by the camera module, abcd, and the center E of the real-world area is projected onto the image when projected onto the image.

On the other hand, when the resolution is 1,000 x 1,200 as illustrated in FIG. 5, the screen display means has a predetermined resolution according to the specification. When the resolution is 1,000 x 1,200, the upper left corner is set as the reference point O1, the horizontal direction is set as x axis, The coordinate value of the screen center point O2 becomes (600, -500).

Since the coordinate value of each position of the screen display means can have a relative value according to the reference point, if the screen center point O2 is set as a reference point, the coordinate value of the center point becomes (0, 0) Becomes (-600, 500).

Since the resolution is determined by the number of pixels of the screen display means, the position of the information displayed on the screen display means can be determined as the position coordinate value of the pixel based on the resolution as described above.

At this time, the diameter of the virtual image area (I in Fig. 4) corresponds to the line forming the diagonal line of the screen display means. If expressed by the number of pixels of the screen display means, the number of pixels forming the diagonal line of the screen display means . For example, when the number of horizontal pixels is 400 and the number of vertical pixels is 300, the number of pixels forming the diameter of the virtual image area is 500.

In the following description, the resolution 400 × 300 is used as an example in order to improve the understanding efficiency.

As described above, the three-dimensional map data corresponding to each POI, the characteristic information such as the name, and the like can all be stored in a database. When the POI extracting unit 130 of the present invention extracts the three-dimensional display POI, The area information generation unit 140 calculates which edge point of the 3D display POI (building or the like) is viewed through the view of the user terminal 10 at the terminal using the current location information transmitted from the terminal.

For example, if the terminal 10 is located on the # 1 plane as shown in FIG. 6, a, b, c, d, e, f, g among the edge points a, c, d, g, and e are displayed on the terminal 10, and if the terminal 10 is located on the # 2 plane, a, b, c, d, . In addition, if the user is located at the front end of the POI 50, since the A_f side of the POI 50 is looked at, a, b, c, and d edge points are displayed to the user terminal.

Therefore, according to the present invention, it is possible to confirm which edge point among the edge points forming the shape of the display POI is seen based on the position of the terminal, and when the detected edge points are projected in two dimensions, the position is projected. It is a matter of course that the absolute coordinate values of the edge points forming the shapes of the POIs are already databaseized.

When each edge point of the three-dimensional display POI is extracted as described above, the area information generator 140 of the present invention generates area information of an exposed POI that is formed when the edge points are projected in two dimensions (S140).

When the area information for each exposed POI is generated as described above, the information processing unit 150 of the present invention generates text information (name, lot number, road name address, etc.) of the POI to be displayed from the display unit of the terminal do.

The positional information can be formed as two-dimensional coordinate values on the x and y axes based on a specific reference point of the screen display means as described above with reference to FIG. 5 and the like. At this time, when the text information of the POI is output to the screen display means of the terminal 10 by generating the text information output position of the POI to be the existing coordinate values in the already generated POI region information, It is possible to avoid overlapping or overlapping at all.

In addition, it is desirable to improve the user's perception and reduce the computational load, so that the real-time information transmission can be realized as much as possible. To this end, the area information generator 140 of the present invention generates area information The area information may be generated only for the exposed POIs located within the reference distance based on the terminal and the area information may not be generated for the exposed POIs beyond the reference distance.

In the case of a POI that is distant from the reference distance based on the terminal, the POI does not greatly affect the user's perception, and a relatively small area is created due to the characteristics of the perspective. Therefore, The computation amount and the computation time can be greatly reduced by performing the selective computation only on the exposing POI.

When the position information to output the text information of the displayed POI is generated as the coordinate value in the area information of each displayed POI, the information processing unit 150 of the present invention displays the text information of the displayed POI along with the generated position information To the terminal (S170).

When information is transmitted from the system 100 of the present invention to the terminal, the terminal 10 transmits text information of each displayed POI to a specific coordinate value position of the screen display means (S180) (see Fig. 11).

Hereinafter, a method of generating and utilizing a two-dimensional projection area of the display POIs by calculating positions where the respective edge points of the three-dimensional display POI are two-dimensionally projected will be described in detail with reference to FIG.

As shown in FIG. 4, when the view direction of the terminal coincides with the Y axis of the real world, the center point of the terminal 10, that is, the camera module is k in FIG. 7, ([theta]) and a corresponding focal length f. On the other hand, the camera module can perform zoom image processing. Since the information about the zoom arrangement is usually a multiple of the focal length, a proportional mathematical operation corresponding to a multiple thereof can be performed in the following description. Meanwhile, FIG. 7 shows a form in which the two axes forming the two dimensions are projected with respect to the y-axis (height direction), and it is needless to say that the x-axis (width direction) is also applicable in view of correspondingness.

In FIG. 7, two objects T1 and T2 having different distances from each other are illustrated. In the case of T1, the distance T1 is distant from the terminal by D1 and the distance T2 is distanced by D2. It is assumed that both of the subjects T1 and T2 have a height of h.

DA1 denotes an area where a real world located at a distance D1 can appear on the image, DA2 denotes a real world located at a distance D2, Means an area that can be expressed on an image.

As shown in Fig. 7, the upper end point of the subject T1 is output at the P1 position in the image region I, and the upper end point of the subject T2 is expressed at the position of P2 in the image region I. Since this object corresponds to the POI and various information (absolute coordinate value, size, width, and the like) about the POI has already been converted into a DB, the computation of the proportional relation as shown in FIG. So that the edge points shown in FIG.

The area information generator 140 of the present invention calculates the coordinate values of the respective edge points by mathematically computing the proportional relationship as described with the following equation.

In Equations (1) and (2), Px and Py are the x and y coordinates of the edge point, Z is the zoom factor, MP is the number of pixels forming the diagonal line of the terminal screen display means, and L, The x coordinate, the z coordinate, and the y coordinate of the 3D point of view POI edge point, which are reference points, correspond to the angle of view information of the camera module. The example shown in FIG. 7 shows a form in which the lower end of the subject is aligned with the horizontal line, that is, the front center direction of the camera.

If the lower end of the subject is downward or upward, unlike the above embodiment, mathematical calculation is performed considering the height as much as it is. Also, from a similar point of view, when the x-coordinate is calculated, the left, center, or right side of the building may be located on the vertical line of the camera. In the following description, the right side is located on the central vertical line. In this case, MP / 2 corresponds to the maximum height (or width) of the virtual image area I in FIG.

For example, the zoom factor is 1, the number of pixels (pixels) according to the resolution of the terminal is 400 × 300, MP is 500, and the specific coordinate value of the edge points among the edge points of the display POI is (6, 43, 105) The coordinate values at which the edge point is projected in two dimensions are calculated using mathematical terms 1 and 2 as follows.

In this case, L, H, and D are calculated by geometric calculation using the three-dimensional absolute coordinate values of the POI edge points stored in the actual POI characteristic information, the coordinate values corresponding to the feet of each axis, and the current position information transmitted from the terminal can do. For example, if it is confirmed that the absolute coordinates of the camera module is (1, -7, 5) through the GPS coordinate value transmitted from the terminal, the relative coordinate value of the specific edge point with the camera module as the reference point is (5, 50, 100). Therefore, L is 5, H is 50, and D is 100. Assuming that? Is 60 degrees, the coordinate values at which the left edge point is projected in two dimensions are as follows.

Through such an operation, the coordinates of the upper left edge point of the POI generate position coordinates (22, 216) projected onto the two-dimensional screen. In this way, the coordinate values in which each edge point is projected in two dimensions are calculated for each edge point displayed through the user view among the edge points of the display POI.

6, if six edge points a, b, c, d, e, and g of the displayed POIs are edge points observed in the user terminal, the coordinate values projected from the respective edge points in two dimensions are, for example, (a). When the respective coordinate values are determined as described above, the real-time information generating unit 140 of the present invention generates the area information using the six coordinates. The method includes the maximum coordinate inclusion method (b) and the inter-coordinate line inclusion method (c) Can be applied. The generated area information of each displayed POI by the maximum coordinate inclusion method is illustrated in FIG.

In this regard, since the edge points of the display POI are composed of three-dimensional coordinate values, the regions formed by the respective coordinate values in the two-dimensional projection can be overlapped as shown in FIG. In order to solve this problem, when the area information of each of the displayed POIs extracted by the area information generating unit 140 is overlapped (S150), the area dividing unit 160 of the present invention extracts, And the area information of each exposed POI is generated (S155).

For example, if the displayed POI corresponding to region C in FIG. 10 is farther away from the user terminal than the displayed POI corresponding to the region D, the overlap region K may exist at a nearby position It is preferable to allocate them to the D region. According to the present invention, since POI regions can be generated independently of each other, when the POI text information is output as described later, each text information is controlled to be outputted only in the unique region, The problem can be effectively overcome.

When the overlapped area is generated, the area dividing unit 160 performs the area allocation processing, and then the information processing unit 150 of the present invention extracts the text information of the displayed POI as the coordinate value in the displayed POI area information And generates output position information. It is preferable to generate the output coordinate information in consideration of various factors such as the number of characters of the text to be output, the size, the width of the adjacent POI area, and the like.

11A is a screen to be confirmed by the user through the screen display means of the user terminal, and FIG. 11B shows a state in which the areas of a plurality of displayed POIs existing in the screen are partitioned, Respectively.

By transmitting the coordinate values present in the divided areas to the terminal, the text information of the corresponding displayed POI can be output together with the image on the screen display means without overlapping with each other. Thus, The virtual additional information corresponding to the video image can be visually confirmed with higher visibility through the real-world image existing in the viewing direction.

As described above, according to the present invention, the real-world image region corresponds to the angle of view or focus of the camera module, and assumes a virtual image region at a position corresponding to the screen display means of the terminal, And the process of calculating the area information of the displayed POI by these have been described. Therefore, in some cases, the displayed POI area formed by the virtual image area may deviate from the image area defined by the screen display means.

When the area of the displayed POI is outside the terminal image area defined by the screen display unit of the terminal, the area information generator 140 of the present invention clips the exposed area of interest into the area corresponding to the terminal image area, And generate the area information of the displayed POI. With this configuration, it is possible to calculate the area of the corresponding displayed POI as the terminal image area defined by the terminal among the virtual image areas, thereby realizing more realistic area information.

Hereinafter, an embodiment of the present invention will be described in which user convenience can be further improved by mutually utilizing path information together with the displayed POI information described above.

The path storage unit 170 of the present invention receives the source information and the destination information from the terminal 10 or another client, and then generates and stores the gait information between the source and destination by various methods. The source information may be input by a user through a terminal or the like, and the GPS position of the current terminal may be used as a source information.

The path storage unit 170 of the present invention may generate path information from information obtained by aligning POIs existing from the source to the destination in order to enhance the synergy effect by utilizing the base point (path) information and the image information together.

When the path storage unit 170 generates and stores path information that is obtained by sorting POIs existing from the source to the destination, the information processing unit 150 of the present invention extracts the POI from the POI If the display POI is a path POI, the text information of the path POI is generated and transmitted so that the text information of the path POI is distinguished from the text information of the display POI other than the path POI.

In this way, when the text information of the path POI existing on the path information is differentiated from the text of the other displayed POI, when the user confirms the front surface through the current screen display means, the path corresponding to the destination The POI can be easily identified, and the user can perform the user-oriented walking path navigation function.

12, when the POI_1 and POI_2 are POIs existing on the path information, the information processing unit 150 of the present invention searches for POI_1 and POI_2 based on the bold, color, size, underline, When the text information is generated by setting the options differently and the text information is transmitted, the user can easily check the POI on the destination set by the outputting of the differentiated text information through the screen display means.

In addition, in the display system 100 of the present invention, since the POI forming the path information exists on the basis of the current user's location, it can be ascertained through the absolute coordinate value and distance of each POI, It is more preferable to provide position information or direction information.

Through this, the user can check the POI corresponding to his / her walking path more quickly and accurately through a single screen, and such processing can be performed until reaching the destination, so that the user can feel the direction in the shortest time So that it can be accurately reached to the destination.

To this end, the information processing unit 150 of the present invention displays more path POIs than the path POI currently displayed on the screen display means of the terminal, based on the current setting information transmitted from the terminal 10 and the location information of the terminal It is preferable to further transmit the view angle guide information such as "rotate the view direction to 20 degrees left ", for example, to the terminal.

Hereinafter, a method for correcting the two-dimensional projection coordinate values of the edge points described above according to the degree of the direction of the camera module will be described in detail with reference to FIGS. In view of the embodiment in which the technical idea of the present invention is realized, the camera module may be guided to the user to look at the front, and the direction angle of the camera module may be within the correction error range. The embodiments of the present invention are based on the technical content of the present invention described above as an additional technical idea.

The three-directional rotation direction of the terminal 10 can be considered as shown in FIG. It can be said that the mutual directionality between the z, y and x direction axes and the terminal shown in FIG. 13 is determined from a relative viewpoint, not from an absolute reference. However, it is preferable that the positions of the cameras (terminals) are made independent and the direction of gravity of the real world is matched with the z axis so as to correspond to the direction of the subject.

13A shows the rotation direction k of the terminal (camera) with reference to the z-axis direction (vertical direction angle), and FIG. 13B shows the rotation direction k with respect to the y- Fig. 13C shows the rotation w in the x-axis direction (direction rotation angle), and Fig.

First, referring to Fig. 14, it will be described how the edge point coordinates on the real world coordinate system are converted into the coordinates on the coordinate system in which the rotation of the terminal (camera) is reflected. Referring to Fig. 15, A method of correcting projection coordinate values will be described.

The coordinate transformation between the three-dimensional coordinate system can be performed according to the following equation (3). In the equation (3), X`, Y` and Z` denote the three-dimensional coordinates in the X'-Y`- , Y, and Z represent the three-dimensional coordinates in the X, Y, and Z axes. Delta_O_X, Delta_O_Y, and Delta_O_Z are the coordinate differences of the origin O_G and O_C in the X-Y-Z axis direction.

15 illustrates that the edge points on the real world coordinate system are converted into the coordinates on the coordinate system in which the rotation angle of the camera is reflected by the equation (3) to be two-dimensionally projected into the virtual image area.

As shown in FIG. 7, all the real-world regions included in the cone having the angle of view (?) Of the camera module are projected to the conical section corresponding to the focal length of the camera module by perspective. This can be defined as a virtual image area as described above, and the actual image area of the camera module in this virtual image area can be distinguished from FIG. 5 and FIG.

That is, as shown in FIG. 15, the virtual image area is a circle equation with the origin of O ₂ in FIG. 5 and the diameter of MP in the X 'and Z' axes, and the actual image area is defined as ± horizontal resolution / 2, Z 'axis and ± vertical resolution / 2. In general, the screen display means of the camera module is configured in a two-dimensional plane, and the coordinates expressing the same are divided into x and y axes as shown in FIG. In this case, the X 'axis corresponds to the x axis of the screen display means of the camera module, and the Z' axis corresponds to the y axis.

The direction of the coordinate axis of the real world and the direction of the camera coordinate axis of the camera module defined in the present invention are defined to specifically describe the present invention and can be redefined according to a specific situation.

15, ∠kO ₂ 'P' is orthogonal and P "can not exceed MP / 2 based on O ₂ in the virtual image region, and [distance from k to O ₂ '× tan P 'exceeding (θ / 2) can not be expressed in the virtual image area.

In addition, the "distance and [O ₂ k from the 'distance to] ratio of × tan (θ / 2)' in the cross-section of O _2, O ₂ The nature of the cone, as shown in Equation (4) below, -P O ₂ - P " and MP / 2.

Since the principle of Equation 4 is also applied to the x-axis and y-axis coordinates constituting O ₂ -P ', the three-dimensional coordinate of the edge point of the real world can be expressed by the two-dimensional coordinates of the screen display means of the camera module.

In Equation (5), Px and Py denote the coordinates of the edge point in the screen display means of the camera module, Z a zoom factor, MP the number of pixels forming the diagonal line of the terminal (camera module) screen display means, L the real- The point corresponds to the coordinates of the X 'axis in the coordinate system of the X', Y 'and Z' axes in which the rotation angle of the camera module is reflected, H denotes the coordinates of the Z 'axis in the same situation, and D denotes the coordinates (visual direction) of the Y' axis.

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 should be understood that various modifications may be made in the ordinary skill in the art.

In addition, each component of the present invention 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 configuration corresponds to a logical component for realizing the technical idea of the present invention, even if each component is integrated or separated, the function performed by the logical configuration of the present invention can be realized. It should be construed that it is within the scope, and that components that perform the same or similar functions are to be interpreted as being within the scope of the present invention regardless of whether their names are consistent.

100: POI display system 110:
120: storage unit 130: POI extraction unit
140: area information generator 150: information processor
160: area division unit 170: information processing unit

Claims (8)

A receiving unit for receiving status information including position information of a terminal, angle-of-view information of a camera module mounted on the terminal, zoom status information, and resolution information of the terminal;
A storage unit for storing characteristic information on the position, shape, and size of the POI and a three-dimensional map database for the POI;
A POI extraction unit for extracting an expression POI that is a POI corresponding to the state information received from the terminal and extracting a three-dimensional expression POI corresponding to the expression POI in the three-dimensional map database;
Generate area information of the presentation POI in which the three-dimensional presentation POI is projected in two dimensions, and using the characteristic information of the presentation POI and the state information, area information of the presentation POI projected onto the screen display means of the terminal. An area information generation unit generating a; And
An information processing unit which generates location information for outputting the text information of the presentation POI as coordinate values in the region information of each generated presentation POI, and transmits the text information of the presentation POI to the terminal together with the generated location information; Including,
The area information generation unit,
An image-based walking path POI presentation system, wherein the coordinate values of the edge points of the exposed POI are calculated by the following equation, and the area information of the expressed POI is generated in a region consisting of the calculated edge point coordinate values. .
[Equation 1]

&Quot; (2) "

In the above equation, Px and Py are the x and y coordinates at which the edge points of the three-dimensional display POI are projected to the two-dimensional display means, Z is the zoom multiple, MP is the number of pixels on the diagonal of the display means, L, H, and D, respectively. Is the x-coordinate, z-coordinate and y-coordinate of the 3D-expressed POI edge point with reference to the camera module as θ is the angle of view information of the camera module. The method of claim 1,
When the area information of each exposed POI extracted by the area information generating unit is overlapped, an area overlapped with an exposed POI located closest to the terminal among the exposed POIs in which the area information is superimposed is allocated And generating area information of each of the displayed POIs,
And the information processing unit generates the location information by using coordinate values in area information of each expressed POI generated by the area divider. The method of claim 1,
Further comprising a route information unit for generating and storing route information obtained by sorting POIs existing from the source to the destination when the source and destination information are transmitted from the terminal,
The information processing unit,
If the expressed POI is a route POI that is a POI existing on the route information, the image-based walking route POI presentation system comprising generating and transmitting text information of the route POI to be distinguished from text information of another expressed POI. . The information processing apparatus according to claim 3,
Based on the current state information transmitted from the terminal, the view angle guide information of the terminal is further transmitted to the terminal so that more path POIs than the path POIs currently displayed on the screen display means of the terminal can be expressed. An image based walking path POI presentation system. delete The method of claim 1, wherein the status information,
And at least one of horizontal rotation angle, vertical rotation angle information, or directional rotation angle information of the camera module generated using a sensor embedded in the terminal.
The area information generation unit,
An image characterized in that each edge point coordinate value is generated by reflecting a position change value corresponding to the horizontal rotation angle, vertical rotation angle, or directional rotation angle to each edge point coordinate value calculated by the equations (1) and (2). Based pedestrian path POI presentation system. 2. The apparatus according to claim 1,
An image-based walking path POI presentation system, wherein the area information is generated for only the presentation POI located within a reference distance based on the terminal. 2. The apparatus according to claim 1,
When the area of the expressed POI is outside the terminal image area defined by the screen display means of the terminal, the area information of the expressed POI is generated by clipping the expressed POI area into an area corresponding to the terminal image area. An image based walking path POI presentation system.

Images