KR101043427B1 - Apparatus and method for embodying stereoscopic image - Google Patents

Abstract

Disclosed are a three-dimensional shape implementing apparatus and method. The three-dimensional shape implementing apparatus for implementing a three-dimensional shape by using the input three-dimensional coordinate values includes a data input unit and a three-dimensional panel unit. The data input unit receives three-dimensional shape implementation data including three-dimensional coordinate values, and the three-dimensional panel portion includes a plurality of display areas having planar coordinate values, and includes a display area having planar coordinate values corresponding to the three-dimensional coordinate values. Adjust the height corresponding to the three-dimensional coordinate value. Thus, even those who cannot see the shape can feel the three-dimensional shape of the shape by using the sense of the hand, and can easily and simply obtain the information of the desired part by touching the display area of the implemented three-dimensional shape.

Three-dimensional shape, 3D shape, touch signal

Description

Apparatus and method for embodying stereoscopic image}

The present invention relates to an apparatus and a method for implementing a three-dimensional shape, and more particularly, to an apparatus and a method for implementing a three-dimensional shape using an input three-dimensional coordinate value.

As times change, the number of people with disabilities in social activities is steadily increasing. This can be said to be due to the development of convenience facilities for the disabled to help people with disabilities along with changes in people's perception of the disabled.

However, despite the development of such facilities, people with disabilities are still experiencing inconveniences, such as the visually impaired.

Since the visually impaired cannot obtain information through the eyes, information is obtained by reading Braille using the tactile sense of the hand, or information is obtained by voice using hearing.

In this case, textual information may be obtained, but imaged information may be difficult to obtain, and the general public may surf the web on a device such as a computer and obtain a large amount of information desired by a user. In addition, there is a limit to fluidly obtaining information desired by a user using a fixed device.

The present invention has been made to solve such a conventional problem, and through the three-dimensional shape implemented to correspond to the three-dimensional coordinate values input from the outside, by using the sense of the hand to feel the three-dimensional feeling of the shape, An object of the present invention is to provide a three-dimensional representation of corresponding information through voice input or text input.

In order to achieve the above object, the three-dimensional shape implementing apparatus according to the present invention includes a data input unit and a three-dimensional panel unit.

The data input unit receives three-dimensional shape implementation data including three-dimensional coordinate values, and the three-dimensional panel portion includes a plurality of display areas having planar coordinate values, and includes a display area having planar coordinate values corresponding to the three-dimensional coordinate values. Adjust the height corresponding to the three-dimensional coordinate value.

Therefore, even a person who cannot see the shape can feel the three-dimensional feeling of the shape according to the input three-dimensional coordinate value through the sense of the hand.

In addition, the three-dimensional shape implementing apparatus according to the present invention corresponds to a display area in which a signal input from a user is detected among the display areas of the three-dimensional panel unit among user-provided information included in the three-dimensional shape implementation data, corresponding to the coordinate value of the display area. The apparatus may further include a user provided information output unit configured to output user provided information.

In addition, the user-provided information may be output in the form of a voice signal.

Therefore, even a person who cannot see the shape can easily and simply obtain the information of the desired part in the implemented three-dimensional shape.

The apparatus for implementing a three-dimensional shape according to the present invention may further include a color information output unit included in the three-dimensional shape implementation data and outputting color information corresponding to the coordinate values of the display area to the display area.

Through the color information, the figures can be realistically shown to those who can see them, and can be used for education of children.

In addition, the stereo coordinate value can be extracted from the 3D shape. Therefore, by directly inputting the shape, it is possible to easily make three-dimensional feeling of general shapes desired by a person who cannot see the shape.

In addition, the three-dimensional shape implementation method according to the present invention is composed of a data input step and a height adjustment step.

In the data input step, three-dimensional shape implementation data including three-dimensional coordinate values are input, and the height adjustment step adjusts a display area having a planar coordinate value corresponding to the three-dimensional coordinate value to a height corresponding to the three-dimensional coordinate value.

In addition, the three-dimensional shape implementation method according to the present invention further comprises a step of outputting the user-provided information after the height adjustment step, in the user-provided information output step of the user-provided information included in the three-dimensional shape implementation data from the user of the display area; The user-provided information corresponding to the coordinate value of the display area may be output to the display area where the input signal is detected.

In this case, the user provided information may be output in the form of a voice signal.

In addition, the three-dimensional shape implementation method according to the present invention further includes a color information output step after the height adjustment step, the color information output step is included in the three-dimensional shape implementation data, the color information corresponding to the coordinate value of the display area Output to the display area is possible.

In addition, the stereo coordinate value can be extracted from the 3D shape.

Through the three-dimensional shape implemented to correspond to the three-dimensional coordinate values input from the outside by the present invention, even those who can not see the shape can feel the three-dimensional feeling of the shape by using the sense of the hand, and display some of the implemented three-dimensional shape By touching the area, the desired part information can be easily and simply obtained by the voice signal.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In order to more clearly understand the present invention, the same reference numerals are used for the same components in different drawings.

1 is a block diagram schematically showing an embodiment of a three-dimensional shape implementing apparatus according to the present invention.

An apparatus for implementing a three-dimensional shape according to the present invention for implementing a three-dimensional shape by using an input three-dimensional coordinate value includes a data input unit 100, a three-dimensional panel unit 200, a user-provided information output unit 300, and a color information output unit. 400.

The data input unit 100 receives three-dimensional shape implementation data including three-dimensional coordinate values, and receives data through an input device such as a keyboard or a mouse or through a data storage device such as a CD or a USB memory. Data stored in the storage autonomy can be input.

The three-dimensional coordinate value refers to the three-dimensional coordinate value of the X, Y, Z axis data of the coordinate value of each pixel of the three-dimensional shape, wherein the X, Y coordinate value represents the plane coordinate value, the Z coordinate value represents the height. . Representative examples of such three-dimensional coordinate values include latitude value (X), longitude value (Y), and altitude value (Z) in a mountain table indicating latitude, longitude, and altitude of a domestic mountain.

The three-dimensional panel unit 200 includes a plurality of display regions having planar coordinate values, and the display region having planar coordinate values corresponding to the stereoscopic coordinate values is adjusted to a height corresponding to the stereoscopic coordinate values to implement a three-dimensional shape.

That is, the three-dimensional panel unit 200 is composed of a plurality of display regions (for example, display regions, such as pixels, which are the smallest unit constituting the screen) having planar coordinate values which are the X and Y coordinate values as described above. Therefore, for example, the display area 1 may be represented as (1, 1), the display area 5 may be represented as (1, 5), or the like.

When the Z coordinate value 7 indicating the height is applied to a display area having coordinate values (1, 1) that coincide with the plane coordinate values (1, 1) included in the stereo coordinate values (1, 1, 7), The height is adjusted by the size of to have a three-dimensional shape. By applying this to the entire display area to implement a three-dimensional shape through the input data, even a person who can not see the shape can feel the three-dimensional feeling of the shape according to the input three-dimensional coordinate value through the sense of the hand.

In this case, the implemented three-dimensional shape is not a three-dimensional shape generally seen using an optical illusion or the like on a plane, but a three-dimensional shape implemented so that a three-dimensional feeling can be felt when actually touched by a hand.

That is, the plurality of display areas of the three-dimensional panel unit 200 may include elasticity that may protrude or return to the original height coordinate value, and may be protruded or returned to its original shape even if there is no elasticity. It will be desirable to be implemented in a material made of a new material that can be transmitted through a transparent light emitting color such as optical fiber or glass.

The user-provided information output unit 300 is a stereoscopic coordinate value of the display area in a display area where a signal input from a user is detected among the display areas of the stereoscopic panel unit 200 among the user-provided information included in the three-dimensional shape implementation data. User-provided information corresponding to may be output.

Here, the signal input from the user refers to a temperature of the hand generated when the user touches a part of the three-dimensional display area by hand, or a pressure applied when the user touches it. The signal input from the user may be detected by a detection sensor installed in the three-dimensional panel unit 200, and the detection sensor may be a temperature sensor, a pressure sensor, a resistance sensor, or the like in response to the signal to be detected.

In addition, the stereoscopic implementation data may further include user-provided information including information on a region corresponding to the stereoscopic coordinate value in addition to the stereoscopic coordinate value described above.

In the case of the mountain table, for example, latitude (X), longitude (Y), and altitude (Z), which represent the location of Hallasan, may be stereoscopic values, and the user-provided information is "Hallasan, located in the center of Jeju Island. "," Halasan has an altitude of 1950 meters, "" Halasan is composed of basalt and is a gentle volcanic volcano. At the top, there is Baeknokdam, a crater lake with a diameter of 500m. " May contain local information.

Such user-provided information may be output in the form of a voice signal, thereby easily and simply delivering information related to the shape to a person who cannot see the shape.

The color information output unit 400 is included in the three-dimensional shape implementation data and may output color information corresponding to the three-dimensional coordinate values of the display area to the display area.

The color information output unit 400 may correspond to a system capable of outputting an LED emitter, a laser emitter, or other colors.

In addition, the stereoscopic implementation data may further include user-provided information or color information in addition to the stereoscopic coordinate values. As mentioned in the above description of the user-provided information, the stereoscopic coordinates may be included in each display area corresponding to the stereoscopic coordinate values. Since each color corresponding to the value is output, the shape can be realistically shown to those who can see the shape, and the three-dimensional shape can be seen even at night.

2 is a view showing an example of the three-dimensional panel unit 200 and the color information output unit 400 according to the present invention.

The height of the display areas constituting the three-dimensional panel unit 200 is determined by using three-dimensional coordinate values of the three-dimensional shape implementation data (including stereoscopic coordinate values, user-provided information, and color information) input through the data input unit 100. You can give a three-dimensional effect by adjusting.

Since the ultrafine pump (diameter 0.1mm-1mm) is installed in the three-dimensional panel part 200, the height of the three-dimensional coordinate value can be adjusted by the Z value, and the ultrafine pump is a hydraulic pump, a pneumatic pump, a hydraulic pump, Or an electromagnet pump or the like can be used.

In Fig. 2, (6, 6), (13, 2), (14, 3), (15, 3), (17, 2), (18, 2), (19, 2), (18, 7) , An example in which the height is adjusted by applying a Z value corresponding to each display area having planar coordinate values of (18, 8) is shown.

In addition, it can be seen that the nine display regions to which the Z values are applied output the color corresponding to each display region by the color information output unit 400.

In FIG. 2, each display area having a three-dimensional shape is shown as a square transparent column (0.1 mm × 0.1 mm to 1 mm × 1 mm), but it may be preferable that the display area can be represented in any shape that is easy to realize three-dimensional shape. .

3 is a flowchart schematically showing an embodiment of a three-dimensional shape implementing method according to the present invention.

When three-dimensional shape implementation data including three-dimensional coordinate values are input from the outside (S100), the height of the display area is adjusted by applying Z coordinate values to the display area having X and Y plane coordinate values corresponding to the three-dimensional coordinate values. Implementing a three-dimensional shape (S110).

Next, it is checked whether the user-provided information is included in the three-dimensional shape implementation data (S120). If the user-provided information is included, the signal is detected only when a signal generated by the user touching a predetermined display area is detected. After the user-provided information corresponding to the display area is output as a voice signal (S130), it is checked whether the color information is included in the three-dimensional shape implementation data (S140).

If the user-provided information is not included, even if a signal from the user is detected, it is immediately checked whether the color information is included without the voice signal output of the user-provided information (S140).

If color information is included in the three-dimensional shape implementation data, the color information corresponding to the three-dimensional coordinate value is output to all display areas and is terminated (S150). If the color information is not included, the process immediately ends.

Figure 4 is a flow chart schematically showing another embodiment of a three-dimensional shape implementation method according to the present invention. The difference from FIG. 3 is that 3D shape is directly input without the 3D shape implementation data.

When the 3D shape to be implemented in three dimensions from the outside is input (S200), the three-dimensional shape implementation data is extracted by applying a data extraction program to the input 3D shape (S210). In the case of FIG. 4, since all three-dimensional coordinate values, user-provided information, and color information can be extracted through a data extraction program, a process of checking whether the user-provided information and the color information are included in the three-dimensional shape implementation data is omitted. .

When the three-dimensional shape implementation data is extracted, the three-dimensional shape is implemented by adjusting the height of the display area by applying the Z coordinate value to the display area having the X and Y plane coordinate values corresponding to the extracted three-dimensional coordinate values (S220).

Then, the user checks whether a signal generated by touching a predetermined display area is detected (S230), and outputs user-provided information corresponding to the detected display area as a voice signal only when the signal is detected. (S240) After outputting the color information corresponding to the three-dimensional coordinate value to all the display area and ends (S250).

5 is a view showing the shape of Halla mountain shown in the mountain road map mentioned in the description of Figure 1, Figure 6 is a view showing an embodiment showing the shape of the Halla mountain of Figure 5 in a three-dimensional shape according to the present invention.

In FIG. 6, when the dark display area marked as normal in Mount Halla is touched by hand, information on Mount Halla may be output as a voice signal.

When the present invention is applied, general maps, directions, guides of buildings, etc. can be implemented in three dimensions in addition to mountain views, and can also be used as bird's eye view of buildings, advertising devices, learning materials for children, stereoscopic electronic frames, stereoscopic electronic boards, stereoscopic monitors, and the like. have.

FIG. 7 is a view illustrating an embodiment in which the present invention is applied to a map or a map among the above-described application examples of the present invention, and instead of a flat monitor in a device including a flat monitor, such as a general notebook computer, a specific monitor according to the present invention. (Stereoscopic monitor) is applied.

The left side shows a 2D image portal site map search using a flat panel monitor, and the right side shows the position search using a 3D monitor.

The stereoscopic monitor device to which the present invention is applied can search for desired location information and map information by voice input or text input as in a map search site such as Naver and bean sprouts, and the user can reduce or enlarge the search result output on the monitor. You can apply this function to adjust the range of the three-dimensional shape on the monitor.

In other words, the three-dimensional monitor device is different from the device including the conventional flat monitor is that the search results can be expressed in a three-dimensional three-dimensional shape through a special monitor (stereoscopic monitor).

So far I looked at the center of the preferred embodiment for the present invention. Those skilled in the art will appreciate that the present invention can be implemented in a modified form without departing from the essential features of the present invention. Therefore, the disclosed embodiments should be considered in descriptive sense only and not for purposes of limitation. The scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the scope will be construed as being included in the present invention.

1 is a block diagram schematically showing an embodiment of a three-dimensional shape implementing device configuration according to the present invention.

2 is a view showing an embodiment of a three-dimensional panel unit and a color information output unit according to the present invention;

Figure 3 is a flow diagram schematically showing an embodiment of a three-dimensional shape implementation method according to the present invention.

Figure 4 is a flow chart schematically showing another embodiment of a three-dimensional shape implementation method according to the present invention.

5 is a view showing the shape of Hallasan shown in the mountain road map mentioned in the description of FIG.

Figure 6 is a view showing an embodiment showing the Hallasan shape of Figure 5 in a three-dimensional shape in accordance with the present invention.

7 is a diagram illustrating an embodiment in which the present invention is applied to a map or a map.

Claims (10)

A data input unit to which stereoscopic implementation data including stereoscopic coordinate values of a stereoscopic shape are input; And A three-dimensional panel unit configured to include a plurality of display areas having plane coordinate values, and adjusting the display area having plane coordinate values corresponding to the stereo coordinate values to a height corresponding to the stereo coordinate values; As a three-dimensional shape implementing device comprising: A user provided to output user provided information corresponding to a coordinate value of the display area to a display area in which a signal input from a user is detected among the user provided information included in the three-dimensional shape implementation data. An information output unit; And A color information output unit included in the three-dimensional shape implementation data and outputting color information corresponding to a coordinate value of the display area to the display area; Three-dimensional shape implementing device further comprising. delete The method of claim 1, The user provided information, An apparatus for implementing a three-dimensional shape, which is output in a voice signal format. delete The method of claim 1, The three-dimensional coordinate value, An apparatus for implementing a three-dimensional shape, which is extracted from a 3D shape. A data input step of inputting three-dimensional shape implementation data including three-dimensional coordinate values; And A height adjusting step of adjusting a display area having a plane coordinate value corresponding to the stereo coordinate value to a height corresponding to the stereo coordinate value; As a three-dimensional shape implementation method comprising: After the height adjustment step, A user-provided information outputting step of outputting user-provided information corresponding to a coordinate value of the display area to a display area in which a signal input from a user is detected among the user-provided information included in the three-dimensional shape implementation data; ; And A color information output step included in the three-dimensional shape implementation data and outputting color information corresponding to a coordinate value of the display area to the display area; Three-dimensional shape implementation method characterized in that it further comprises. delete The method of claim 6, The user provided information, Three-dimensional shape implementation method characterized in that the output in the form of a voice signal. delete The method of claim 6, The three-dimensional coordinate value, Three-dimensional shape implementation method characterized in that the extraction from the 3D shape.

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